Bypass Circuit and Method to Bypass Power Modules in Power System

ABSTRACT

A method and apparatus to bypass, using bypass circuits, non-operating power modules in a power system. Multiple power sources are coupled to inputs of respective power modules. Multiple bypass circuits have respective terminals operatively coupled to the respective outputs of the power modules. The outputs of the power modules are coupled in a series connection and the series connection is coupled across a load. Each bypass circuit includes a switch operatively coupled across a first input of a circuit and an output of a power module. A feedback circuit includes a second input coupled to an output of the circuit. A coupling circuit includes a third input coupled to an output of the feedback circuit. The coupling circuit includes an output operatively coupled across the switch. The switch is biased to provide the bypass responsive to a voltage of the output of the circuit and the voltage of the power module output.

RELATED APPLICATIONS

This application claims priority to provisional application Ser. No. 62/478,366, filed Mar. 29, 2017, entitled “Bypass Circuit”, and this application also claims priority to provisional application Ser. No. 62/547,221, filed Aug. 18, 2017, entitled “Bypass of a Photovoltaic Module”, the entire contents of which are incorporated herein by reference.

BACKGROUND

Power systems may have multiple power generators coupled to power devices. Power systems may be configured to control the power harvesting and extracting from the power generators, and in some embodiments, bypass one or more power generators and/or power devices. In some scenarios, the power system may operate more efficiently by bypassing one or more power devices. In some scenarios, one or more power devices may experience potentially unsafe conditions, such as over-heating or over-voltage. Safety regulations may require to disconnect, or bypass unsafe parts of the system. Safety regulations may require to lowering the voltage or heat of a power system or power device or to distance and/or electrically separate a high voltage point from a system power device. One way to lower the voltage or to distance and/or separate the high voltage point from the system power device may be to bypass a power device.

Also, bypass circuits, such as bypass diodes or free-wheeling diodes, may be wired in parallel across the outputs of intercoupled power sources such as photovoltaic (PV) panels, batteries or generators, to provide a current path around them in the event that a power source becomes faulty by failing to provide power on its output. For example, the use of bypass circuits with regard to intercoupled PV panels, may allow a series string of coupled PV cells, PV panels and/or a series string of serially connected power devices outputs to continue supplying power to a load at a reduced voltage rather than no power at all, since the use of bypass circuits may allow continued current draw around the output of a faulty PV panel output and/or power device. Certain bypass circuits may incur significant losses (e.g., due to a substantial voltage drop across a conducting bypass circuit). There is a need for efficient bypass circuits that may allow bypassing power sources and/or other circuit elements without incurring significant losses.

SUMMARY

The following summary is a short summary of some of the inventive concepts for illustrative purposes only, and is not intended to limit or constrain the inventions and examples in the detailed description. One skilled in the art will recognize other novel combinations and features from the detailed description.

Illustrative embodiments disclosed herein may be with respect to power sources in a power system and may consider the interconnection of various groups of power sources. Each group of power sources may contain different types of power derived from both renewable energy sources such as provided from sunlight, wind or wave power, and non-renewable energy sources such as fuel used to drive turbines or generators, for example. Some illustrative embodiments may consider the connection of DC sources to a load via multiple power modules.

Illustrative embodiments disclosed herein may include a power system utilized to supply power to a load and/or a storage device. The power system may include various inter connections of groups of direct current (DC) power sources that also may be connected in various series, parallel, series parallel and parallel series combinations, for example.

More specifically, illustrative embodiments disclosed herein include bypass circuits that may be utilized, for example, on power module outputs in a series connection of the power module outputs or on power sources outputs in a series connection of the power sources outputs or in a combination thereof. By way of example, the power modules inputs may be coupled respectively to multiple direct current AC or DC power sources. The series connections may be coupled across a load. The use of bypass circuits according to illustrative embodiments may allow a series string of power sources and/or power module outputs to continue to efficiently supply power to a load at a reduced voltage rather than no power at all, since the use of bypass circuits may allow continued current draw around the output of a faulty powers source and/or power module output.

Possible features of bypass circuits disclosed herein may include continuous bypass operation to provide a potential bypass of serially coupled power module outputs and/or power source outputs. In some embodiments, the bypass circuits may provide a bypass path during a low level of power production of an associated DC power source. In some embodiments, the bypass circuits may provide a bypass path when low power may be being produced on the output of at least one of the power modules compared to other power module outputs. In some embodiments, the bypass circuits may utilize a switch, and may have low power loss compared to the use of other passive or active bypass devices, for both high and low current flow through a series connection of power modules and/or power sources. Illustrative bypass circuits may include additional circuitry that may be adapted to provide or increase a bias voltage to the switch. The bias voltage may enable operation of the switch below minimal operating parameters normally provided by a series connection of the power modules and/or power sources outputs for the switch.

In some embodiments, a bypass circuit with a switch is provided, which may be operatively coupled across a first input of a circuit and an output of a power source. A feedback circuit may be provided that includes a second input coupled to a first output of the circuit and a coupling circuit including a third input may be coupled to a second output of the feedback circuit. The coupling circuit may include a third output operatively attached across the switch. The coupling circuit may include a transformer adapted to increase a voltage on the third output from the second output. The voltage enables operation of the switch below its minimal operating parameters. The switch may be continuously biased across the third output responsive to a voltage of the first output of the circuit and the voltage of the power source.

The circuit may be: a Colpitts oscillator circuit, a Hartley oscillator circuit, a relaxation oscillator circuit, an Armstrong oscillator circuit, a Clapp oscillator circuit, a Colpitts oscillator circuit, a Cross-coupled oscillator circuit, a Meissner oscillator circuit, an Opto-electronic oscillator circuit, a Pierce oscillator circuit, a Phase-shift oscillator circuit, a Robinson oscillator circuit, a Tri-tet oscillator circuit, a Vackář oscillator circuit, a Wien bridge oscillator circuit, a free running oscillator circuit, a charge pump circuit, a pulse width modulator circuit, a direct current (DC) to DC converter, or a blocking oscillator circuit.

In some embodiments, a power system is provided, in which the power system may include multiple power sources coupled to the inputs of respective power modules. Multiple bypass circuits may be operatively coupled to the respective outputs of the power modules. The outputs of the power modules may be coupled in a series connection applied across a load. Each respective bypass circuit may be biased in a continuous manner responsive to the respective voltages present across or currents through respective outputs of the power modules.

The outputs of the power modules may be coupled in parallel across the load. An inverter module may be operatively coupled between the series connection and the load. A second power module may be operatively coupled between the series connection and the load.

Each of the bypass circuits may include a switch operatively coupled across a first input of a circuit and a power source. A feedback circuit including a second input may be coupled to a first output of the oscillator, and a coupling circuit including a third input may be coupled to a second output of the feedback circuit. The coupling circuit includes a third output operatively attached across the switch. The switch may be continuously biased across the third output responsive to a voltage of the first output of the oscillator and the voltage of the power source. The coupling circuit may include a transformer that may be adapted to increase a voltage on the third output coupled from the second output. The voltage may enable operation of the switch below its minimal operating parameters.

Some embodiments are directed to a method to provide a bypass of non-operating power modules in a power system. Multiple power sources may be coupled to the inputs of respective power modules. Multiple bypass circuits terminals may be operatively coupled to the respective outputs of the power modules. The outputs of the power modules may be coupled in a series connection and applying the series connection across a load. A bias may be provided to each of the bypass circuits terminals in a continuous manner. Each bypass circuits terminals may be responsive to the respective voltages present across or currents through respective outputs of the power modules. A switch that includes a circuit may be coupled across the bypass circuits terminals, and a feedback circuit may be coupled to the switch. A coupling circuit may be coupled to the feedback circuit. The coupling circuit may include a transformer that may be adapted to increase a bias voltage to the switch. The bias voltage may enable operation of the switch below minimal operating parameters compared to operating parameters provided by the outputs of the power modules that may not be sufficient.

The outputs of at least one power sources may be coupled in a second series connection. The second series connection may be applied across at least one of the power modules inputs, and at least one of the bypass circuits terminals may be coupled to the output of at least one power sources outputs responsive to the voltages present across or currents through the second series connection. An inverter module may be coupled between the series connection and the load. A second power module may be coupled between the series connection and the load.

In some embodiments, a power system includes one or more strings of photovoltaic (PV) power generators connected in parallel and/or series. A PV power generator may be a PV cell, substring of PV cells, a PV panel and/or a string of PV panels. One or more of the power generators may be coupled to a power device (e.g., optimizer/micro inverter) configured to extract the power from the power generator and transfer it to the coupled string. The one or more strings may be coupled to a system power device (e.g., inverter, power converter, storage device, junction box) configured to combine the power transferred by the strings.

In some embodiments, the power device may have a power converter configured to convert the power extracted from a coupled power generator. The power device may include a communication device configured to receive and/or send a signal from/to a corresponding communication device. For example, the communication device may be configured to receive a keep-alive signal from a transceiver in the system power device, where the keep-alive signal may be an enabling signal for the power device and when the keep-alive signal stops, the power device may be configured to go into bypass.

In some embodiments, the power device may have one or more sensors/sensor interfaces. The one or more sensors/sensor interfaces may be configured to measure and/or sense one or more parameters in and surrounding the power device. For example, the sensors/sensor interfaces may measure the voltage between any two points in the power device, the temperature in and/or surrounding the power device, the current at the input and/or at the output of the power device, etc. The measurements sensed by the sensors/sensor interfaces may signal a controller configured to receive the measurements. The controller may be configured to control the enablement and/or disablement of one or more circuits and devices in the power device. The controller may be configured to control a Maximum Power Point Tracking (MPPT) circuit, safety devices, and a memory device. According to some aspects, the controller may be configured to enable and/or disable a bypass circuit. The bypass circuit may be configured to bypass the inputs to the power device by short circuiting the inputs to the power device.

According to some aspects, the bypass circuit may be configured to disconnect the power generator from the inputs to the power device. According to some aspects, the bypass circuit may be configured to short circuit the outputs of the power device, and in some embodiments, disconnect the inputs of the power converter from the outputs of the power device. One or more circuits and devices may receive power from an auxiliary power circuit. According to some aspects, the auxiliary power circuit may receive power from the inputs of the power device. According to some aspects, the auxiliary power circuit may be coupled to the outputs of the bypass circuit. The auxiliary power circuit may draw power from the bypass circuit at a voltage value of the outputs of the bypass circuit. The voltage value at the outputs of the bypass circuit may vary between when the bypass circuit is OFF, when the voltage may be similar to the voltage on the outputs of the power device, and when the bypass circuit is ON, when the voltage may be the voltage across one or more switches in the bypass circuit.

In some embodiments, the auxiliary power circuit may have a power converter configured to output power suitable for the one or more devices and circuits configured to receive power from the auxiliary power circuit. According to some aspects, the auxiliary power circuit may be coupled to the inputs of the power device and the outputs of the bypass circuit. According to some aspects, the auxiliary power circuit may have a logic block configured to determine where to draw power from, for example, from the inputs of the power device and/or from the outputs of the bypass circuit.

As noted above, this Summary is merely a summary of some of the features described herein. It is not exhaustive, and it is not to be a limitation on the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects, and advantages of the present disclosure will become better understood with regard to the following description, claims, and drawings. The present disclosure is illustrated by way of example, and not limited by, the accompanying figures.

FIG. 1A shows a power system, according to one or more illustrative embodiments.

FIG. 1B illustrates circuitry that may be found in a power device such as a power module, according to one or more illustrative embodiments.

FIG. 1C shows a buck+boost circuit implementation for a power converter, g to one or more illustrative embodiments.

FIG. 1D shows a buck circuit implementation for a power converter, according to one or more illustrative embodiments.

FIG. 1E shows a power system, according to one or more illustrative embodiments.

FIG. 1F shows a power system, according to one or more illustrative embodiments.

FIG. 1G is part block diagram, part schematic of a bypass circuit, according to one or more illustrative embodiments.

FIG. 1H shows a flowchart of a method, according to one illustrative embodiments.

FIG. 1I shows further details of a coupling circuit, a bypass switch and a circuit n a bypass circuit, according to one or more illustrative embodiments.

FIG. 1J shows further details of the circuit in the bypass circuit of FIG. 1I, according to one or more illustrative embodiments.

FIG. 1K shows a flow chart of a method for a bypass circuit, according to one or more illustrative embodiments.

FIG. 1L shows transient traces of measurements made on a working design of the bypass circuit shown in FIG. 1i , according to one or e illustrative embodiments.

FIG. 1M shows steady state measurement traces of a bypass circuit shown in FIG. 1i , according to one or more illustrative embodiments.

FIG. 1N shows steady state measurement traces of a bypass circuit, according to one or more illustrative embodiments.

FIG. 1O is a part circuit diagram, part schematic of a bypass circuit, according to one or more illustrative embodiments.

FIG. 1P is a part circuit diagram, part schematic of a bypass circuit, according to one or more illustrative embodiments.

FIG. 1Q shows further details of a bypass circuit, according to one or more illustrative embodiments.

FIG. 1R shows a flow chart showing further details of a step shown in FIG. 1H, according to one or more illustrative embodiments.

FIG. 1S shows a power system, according to one or more illustrative embodiments.

FIG. 1T is part schematic, part block diagram of a power system including multiple power devices and multiple power generators, according to one or more illustrative embodiments.

FIG. 2 is a block diagram of a power device, according to one or more illustrative embodiments.

FIGS. 2A and 2B are schematics of implementations of a bypass circuit, according to one or more illustrative embodiments.

FIG. 2C is a block diagram of part of a power device, according to one or more illustrative embodiments.

FIG. 3 is a part schematic, part block diagram of a power device, according to one or more illustrative embodiments.

FIG. 3A is a part schematic, part block diagram of an auxiliary power circuit connected to a bypass circuit, according to one or more illustrative embodiments.

FIG. 3B is a part schematic, part block diagram of a power device, according to one or more illustrative embodiments.

FIG. 3C is a schematic of a bypass circuit, according to one or more illustrative embodiments.

FIG. 4 is a part schematic, part block diagram of a power device, according to one or more illustrative embodiments.

FIG. 4A is a schematic diagram of selection circuit configured to activate bypass, according to one or more illustrative embodiments.

FIG. 4B shows a flow chart of a method for activating a bypass switch, according to one or more illustrative embodiments.

FIG. 5 shows a flow chart of a method for operating a bypass circuit, according to one or more illustrative embodiments.

FIG. 6A illustrates a part schematic, part circuit diagram of a bypass circuit, according to one or more illustrative embodiments.

FIG. 6B illustrates a part schematic, part circuit diagram of a circuit included in a bypass circuit, according to one or more illustrative embodiments.

FIG. 6C illustrates a part schematic, part block diagram of a power device, according to one or more illustrative embodiments.

FIG. 6D illustrates a part schematic, part block diagram of a power device, according to one or more illustrative embodiments.

DETAILED DESCRIPTION

In the following description of various illustrative embodiments, reference is made to the accompanying drawings, which form a part hereof, and in which is shown, by way of illustration, various embodiments in which aspects of the disclosure may be practiced. It is to be understood that other embodiments may be utilized and structural and functional modifications may be made, without departing from the scope of the present disclosure.

By way of introduction, features of one or more embodiments may be directed to a power system and bypass circuits that may be utilized, for example, on power module outputs in a series connection of the power module outputs. Each power module may have inputs coupled to one or more direct current (DC) power sources. The series connection may be coupled across a load. Possible features of bypass circuits disclosed herein may include continuous bypass operation to provide a potential bypass of serially coupled power module outputs and/or power source outputs. In some embodiments, the bypass circuits may provide a bypass path during a low level of power production of an associated DC power source. In some embodiments, the bypass circuits may provide a bypass path when low power may be being produced on the output of at least one of the power modules compared to other power module outputs. In some embodiments, the bypass circuits may utilize a switch, and may have low power loss compared to the use of other passive or active bypass devices, for both high and low current flow through a series connection of power modules and/or power sources. Illustrative bypass circuits may include additional circuitry that may be adapted to provide or increase a bias voltage to the switch. The bias voltage may enable operation of the switch below minimal operating parameters normally provided by a series connection of the power modules and/or power sources outputs for the switch.

The term “multiple” as used here in the detailed description indicates the property of having or involving several parts, elements, or members. The claim term “a plurality of” as used herein in the claims section finds support in the description with use of the term “multiple” and/or other plural forms. Other plural forms may include for example regular nouns that form their plurals by adding either the letter ‘s’ or ‘es’ so that the plural of converter is converters or the plural of switch is switches for example.

The claim terms “comprise”, “comprises” and/or “comprising” as used herein in the claims section finds support in the description with use of the terms “include”, “includes” and/or “including”.

Reference is made to FIG. 1A, which shows a power system 100 a, according to illustrative embodiments. Connection configuration 104 a includes power source 101 with direct current (DC) output terminals coupled to input terminals of power module 103. Connection configuration 104 b includes two power sources 101 coupled in a series connection, with direct current (DC) output terminals of the series connection coupled to the input terminals of power module 103. The outputs of power modules 103 may be coupled in series to form a series coupled string of power module 103 outputs. The series coupled string of power module 103 outputs have a total voltage output Vstring that may be coupled across the input of power device 139. Power modules 103 may be a direct current (DC) to DC converter. Alternatively, total voltage output Vstring may be coupled across load 107. The outputs of power modules 103 may be coupled in a series string to which more power modules 103 may be added in order to provide the required input voltage (Vstring) to power device 139. Power device 139 may be, for example, a direct current (DC) to DC converter or may be DC to alternating current (AC) inverter supplying power to load 107. In some embodiments, power device 139 may be a combiner box for combining multiple strings of power sources, a safety device (e.g., a ground fault detector and/or or safety switch) and/or a monitoring device configured to measure, monitor and/or report operational parameters associated with power system 100 a. Load 107 may be, for example, a battery, an alternating current (AC) grid, a DC grid, or a DC to AC inverter.

A positive (+) output terminal of power module 103 in connection configuration 104 a may be coupled to a negative (−) output terminal of another power module 103 or to a negative (−) output terminal of power module 103 in connection configuration 104 b. Bypass diodes BPD1 may be provided with cathodes coupled to respective positive (+) output terminals of power sources 101 and anodes coupled to respective negative (−) output terminals of power sources 101. Bypass diodes BPD1 may be similarly coupled across the outputs of power modules 103. In connection configuration 104 b two power sources 101 including their respective bypass diodes BPD1 are connected in series to provide a voltage (V1+V2). The voltage (V1+V2) may then be applied to the input of a power module 103 at terminals C and D of the power module 103. In connection configuration 104 a, a single power source 101 with bypass diode BPD1 provides a voltage V3. The voltage V3 is applied to the input of a power module 103 at terminals C and D of power module 103. Multiple outputs of connection configurations 104 a/104 b may be wired in series to give a string voltage (Vstring) that may be applied to the input of power device 139.

In the descriptions that follow, power sources 101 may be a photovoltaic (PV) generator, for example, a PV cell, a series string of PV cells, a parallel connection of serially coupled PV strings of PV cells, a photovoltaic or solar panel, DC generator, a battery, or a fuel cell. In some embodiments, for example where power source 101 includes multiple serially coupled power sources such as PV substrings or PV cells, bypass diodes BPD1 may be replaced or complemented by additional diodes coupled in parallel to each serially coupled power source 101. DC sources of power for power sources 101 may also be derived from rectified or converted sources of alternating current (AC) provided from a switched mode power supply, dynamo or alternator, for example.

Operation of bypass diodes BPD1 may be illustrated, by way of example, where power sources 101 may be photovoltaic panels. A power source in connection configuration 104 b is shown shaded with a shade 155. As such, the voltage V2 of the shaded power source 101 may have opposite polarity with respect to the other unshaded panels with respect to their voltages V1 and V3. The opposite polarity may be as a result of restricted current flow of Ipanel so that the non-shaded panel may attempt to push the current through power module 103. The attempt at pushing current flow may cause bypass diodes BPD1 to become forward biased. A function of bypass diodes BPD1 may therefore provide the function of bypassing a shaded panel and/or non-functioning power module 103 output in a series string of serially connected power module outputs 103. Without bypass diodes BPD1 on the outputs of power sources 101, voltage V2 may oppose the flow of current Ipanel so that current Ipanel may be substantially zero. Substantially zero current Ipanel means that power module 103 in connection configuration 104 b may be inoperative and therefore, both current Istring and voltage Vstring to the input of power device 139 may be substantially zero.

However, with bypass diodes BPD1, the opposite polarity of V2 may be applied across the bypass diode BPD1 which forward biases bypass diode BPD1. Voltages V1 and V3 as such reverse bias their respective bypass diodes BPD1. The forward bias of V2 applied bypass diode BPD1 causes current Ipanel to flow from anode to cathode of bypass diode BPD1 at the output of the shaded power source 101.

Therefore, bypass diodes BPD1 provide a potential parallel path of current conduction around a panel or power source 101 that is not working or is shaded with shade 155. In general, a working panel applies a reverse bias voltage across bypass diodes, and a non-working or shaded panel applies a forward bias voltage across bypass diodes BPD1.

Bypass diodes BPD1 may be coupled across the output of power modules 103. If a power module 103 becomes inactive in a series string of power module outputs, current (Istring) attempting to pass through the inactive power module 103 may be offered an alternative, parallel path. The alternative, parallel path may be around the output of the inactive power module 103 via bypass diode BPD1. Rather than a forcing of current (Istring) through an inactive power module 103 output, the flow of current (Istring) may cause bypass diode BPD1 to become forward biased. The forward biasing of bypass diode BPD1 may cause current Istring to flow from anode to cathode of bypass diode BPD1. Therefore, bypass diodes BPD1 may provide a potential parallel path of current conduction around a nonfunctioning power module 103 output in a series string of coupled power module 103 outputs.

Reference is now made to FIG. 1B, which illustrates circuitry that may be found in a power device such as power module 103, according to illustrative embodiments. Power module 103 may be similar to or the same as power module 103 shown in FIG. 1A. In some embodiments, power module 103 may include power circuit 135. Power circuit 135 may include a direct current-direct current (DC/DC) converter such as a Buck, Boost, Buck/Boost, Buck+Boost, Cuk, Flyback and/or forward converter, or a charge pump. In some embodiments, power circuit 135 may include a direct current-alternating current (DC/AC) converter (also known as an inverter), such as a micro-inverter. Power circuit 135 may have two input terminals and two output terminals, which may be the same as the input terminals and output terminals of power module 103. In some embodiments, power module 103 may include Maximum Power Point Tracking (MPPT) circuit 138, configured to extract increased power from a power source the power device may be coupled to. In some embodiments, power circuit 135 may include MPPT functionality. In some embodiments, MPPT circuit 138 may implement impedance matching algorithms to extract increased power from a power source the power device may be coupled to power module 103 may further include controller 105 such as a microprocessor, Digital Signal Processor (DSP), Application-Specific Integrated Circuit (ASIC) and/or a Field Programmable Gate Array (FPGA).

Still referring to FIG. 1B, controller 105 may control and/or communicate with other elements of power module 103 over common bus 190. In some embodiments, power module 103 may include circuitry and/or sensors/sensor interfaces 125 configured to measure parameters directly or receive measured parameters from coupled sensors and/or sensor interfaces 125 configured to measure parameters on or near the power source, such as the voltage and/or current output by the power source and/or the power output by the power source. In some embodiments, the power source may be a photovoltaic (PV) generator including PV cells, and a sensor or sensor interface may directly measure or receive measurements of the irradiance received by the PV cells, and/or the temperature on or near the PV generator.

Still referring to FIG. 1B, in some embodiments, power module 103 may include communication interface 129, configured to transmit and/or receive data and/or commands from other devices. Communication interface 129 may communicate using Power Line Communication (PLC) technology, acoustic communications technology, or additional technologies such as ZigBee™, Wi-Fi, Bluetooth™, cellular communication or other wireless methods. In some embodiments, power module 103 may include memory 123, for logging measurements taken by sensor(s)/sensor interfaces 125 to store code, operational protocols or other operating information. Memory 123 may be flash, Electrically Erasable Programmable Read-Only Memory (EEPROM), Random Access Memory (RAM), Solid State Devices (SSD) or other types of appropriate memory devices.

Still referring to FIG. 1B, in some embodiments, power module 103 may include safety devices 160 (e.g., fuses, circuit breakers and Residual Current Detectors). Safety devices 160 may be passive or active. For example, safety devices 160 may include one or more passive fuses disposed within power module 103 where the element of the fuse may be designed to melt and disintegrate when excess current above the rating of the fuse flows through it, to thereby disconnect part of power module 103 so as to avoid damage. In some embodiments, safety devices 160 may include active disconnect switches, configured to receive commands from a controller (e.g., controller 105, or an external controller) to short-circuit and/or disconnect portions of power module 103, or configured to short-circuit and/or disconnect portions of power module 103 in response to a measurement measured by a sensor (e.g., a measurement measured or obtained by sensors/sensor interfaces 125). In some embodiments, power module 103 may include auxiliary power circuit 162, configured to receive power from a power source coupled to power module 103, and output power suitable for operating other circuitry components (e.g., controller 105, communication interface 129, etc.). Communication, electrical coupling and/or data-sharing between the various components of power module 103 may be carried out over common bus 190.

Reference is made to FIG. 1C, which shows a buck+boost circuit implementation for power circuit 135, according to one or more illustrative embodiments. The buck+boost circuit implementation for power circuit 135 utilizes metal oxide semiconductor field effect transistors (MOSFETs) for switches S1, S2, S3 and S4. The sources of switches S1, S2, S3 and S4 are referred to as first terminals, the drains of S1, S2, S3 and S4 are referred to second terminals, and the gates of S1, S2, S3 and S4 are referred to as third terminals. Capacitor Cin may be coupled in parallel across the respective positive (+) and negative (−) input terminals C and D of the buck+boost circuit, where the voltage may be indicated as VIN. Capacitor Cout may be coupled in parallel across the respective positive (+) and negative (−) output terminals A and B of the buck+boost circuit, where the voltage may be indicated as VOUT. First terminals of switches S3 and S2 may couple to the common negative (−) output and input terminals of the buck+boost circuit. A second terminal of switch S1 may couple to the positive (+) input terminal and a first terminal of switch S1 may couple to a second terminal of switch S3. A second terminal of switch S4 may couple to the positive (+) output terminal and a first terminal of switch S4 may couple to the second terminals of switch S2. Inductor L1 may couple respectively between the second terminals of switches S3 and S4. Third terminals of switches S1, S2, S3 and S4 may be operatively coupled to controller 105 (not shown in FIG. 1C).

Switches S1, S2, S3 and S4 may be implemented using semiconductor devices, for example, metal oxide semiconductor field effect transistors (MOSFETs), insulated gate bipolar transistors (IGBTs), bipolar junction transistors (BJTs), Darlington transistor, diode, silicon controlled rectifier (SCR), Diac, Triac or other semiconductor switches known in the art. By way of example, switches S1, S2, S3 and S4 may be implemented by use of bipolar junction transistors, where the collectors, emitters and bases may refer to first terminals, second terminals and third terminals described and defined above. Switches S1, S2, S3 and S4 may be implemented using mechanical switch contacts such as hand operated switches or electro-mechanically operated switches such as relays, for example. Similarly, implementation for power module 103 may include, for example, a buck circuit, a boost circuit, a buck/boost circuit, a Flyback circuit, a Forward circuit, a charge pump, a Cuk converter or any other circuit that may be utilized to convert power on the input of power module 103 to the output of power module 103.

Power module 103 may include or be operatively attached to a maximum power point tracking (MPPT) circuit (MPPT 138 for example). The MPPT circuit may also be operatively coupled to controller 105 or another controller 105 included in power module 103 that may be designated as a primary controller. A primary controller in power module 103 may communicatively control one or more other power modules 103 that may include controllers known as secondary controllers. Once a primary/secondary relationship is established, a direction of control may be from the primary controller to the secondary controllers. The MPPT circuit under control of a primary and/or central controller 105 may be utilized to increase power extraction from power sources 101 and/or to control voltage and/or current supplied to load 107.

Reference is made to FIG. 1D, which shows a buck circuit implementation for power circuit 135, according to one or more illustrative embodiments. The buck circuit implementation for power circuit 135 utilizes metal oxide semiconductor field effect transistors (MOSFETs) for switches S1 and S3. The sources of switches S1 and S3 are referred to as first terminals, the drains of S1 and S3 are referred to second terminals, and the gates of S1 and S3 are referred to as third terminals. Capacitor Cin may be coupled in parallel across the respective positive (+) and negative (−) input terminals C and D of the buck circuit, where the voltage may be indicated as VIN. Output terminals A and B of the buck circuit may be indicated as having an output voltage VOUT. A first terminal of switch S3 may couple to the common negative (−) output and input terminals of the buck circuit. A second terminal of switch S1 may couple to the positive (+) input terminal, and a first terminal of switch S1 may couple to a second terminal of switch S3. Inductor L1 may couple respectively between the second terminal of switches S3 and terminal A. Third terminals of switches S1 and S3 may be operatively coupled to controller 105 (not shown in FIG. 1D).

Reference is now made to FIG. 1E, which shows a power system 100, according to illustrative embodiments. Power harvesting system 100 may be similar to power harvesting system 100 a but might not include bypass diodes BPD1. Instead of or in addition to bypass diodes BPD1, bypass circuits 115 having terminals A and B may couple across the output terminals of power modules 103. Bypass circuit 115 provides a switch between terminals A and B, so that when the switch is ON a substantially short circuit exists between terminals A and B, and when the switch is OFF a substantially open circuit exists between terminals A and B. Bypass circuits 115, in accordance with illustrative embodiments disclosed herein, may provide certain advantages when compared to passive bypass diodes (e.g. BPD1).

Reference is made to FIG. 1F, which shows a power system 100 b, according to illustrative embodiments. Multiple strings of serially connected connection configurations 104 a and 104 b are shown in FIG. 1E. The strings are connected in parallel across the input of power device 139, with voltage input to power device 139 shown as Vstring. Power device 139 may be a direct current (DC) to DC converter or may be a DC to alternating current (AC) inverter supplying power to load 107. Power harvesting system 100 b may be similar to power harvesting system 100 but might not include bypass diodes BPD1. Instead of or in addition to bypass diodes BPD1, bypass circuits 115 having terminals A and B may be implemented in connection configurations 104 a and 104 b as shown in FIG. 1E. In general, any number of connection combinations of multiple connection configurations 104 a/104 b may include DC power sources 101 of differing types so that one connection configuration has photovoltaic panels, for example, while another connection configuration has wind powered DC generators.

Reference is now made to FIG. 1G, which is part schematic, part block diagram of bypass circuit 115, according to illustrative embodiments. An output of a circuit 111 may couple to a coupling circuit 120 by coupling unit 120 a. Coupling unit 120 a may be a part of coupling circuit 120, a part of the output of circuit 111 and/or portions of both coupling circuit 120 and circuit 111. Coupling unit 120 a may allow a coupling to provide a feedback path via a circuit between the output of circuit 111 and coupling circuit 120. The coupling may be a direct electrical connection and/or coupling circuitry between the output of circuit 111 and coupling circuit 120. The coupling may alternatively be a capacitive coupling between the output of circuit 111 and coupling circuit 120. The coupling may alternatively be an inductive coupling between the output of circuit 111 and coupling circuit 120. The inductive coupling may include a mutual inductive coupling between two inductors that may include a common direct electrical connection point shared between the two inductors. The inductive coupling may alternatively have two inductors that are both wound on a core. The core may allow a transformer coupling arrangement between the two inductors whereby a common direct electrical connection point is not shared between the two inductors.

The output of coupling circuit 120 may couple to the input of switch BP1. The output of coupling circuit 120 may be such that switch BP1 may be either ON or OFF. The poles of switch BP1 may couple to terminals A and B, which may also be coupled across the input of circuit 111. Terminals A and B may also couple across output terminals of a power module 103 (not explicitly shown). When switch BP1 is ON; the power module 103 might be not functioning and string current Istring may flow through switch BP1. When switch BP1 is OFF; the power module 103 may be functioning and string current Istring may flow through the output of the power module 103. Switch BP1 is shown as a MOSFET where a diode PD1 is coupled across the drain and source of the MOSFET. Diode PD1 may be an intrinsic part of the MOSFET as a result of a structure of the MOSFET. The structure of the MOSFET as such has an intrinsic p-n junction (diode) coupled between the drain and source. The intrinsic p-n junction (diode) of a MOSFET may be referred to as a body diode or a parasitic diode. Other semiconductor devices may be used for switch BP1 which do not have an intrinsic p-n junction (diode) between terminals A and B, in which case a diode may be additionally coupled across terminals A and B. An additional switch wire C11 may connect between coupling circuit 120 and circuit 111.

Switch BP1 may implemented using the switches that may already exist in power circuit 135. With reference to FIG. 1C, which shows a buck+boost circuit for power circuit 135, BP1 may implemented with the use of switches S2 and S4 across nodes A and B. Similarly, with reference to FIG. 1D, which shows a buck circuit for power circuit 135, switch BP1 may implemented with the use of switch S3 across nodes A and B via inductor L1. In descriptions, which follow of the Figures, diodes shown coupled across a switch may be intrinsic to the switch or may be additionally coupled across the switch.

Reference is now made again to FIG. 1G and to FIG. 1H, which shows a flow chart of a method 1000, according to illustrative embodiments. The flow chart of method 1000 is used to explain the operation of the part schematic, part block diagram of bypass circuit 115 shown in FIG. 1G. The flow chart of method 1000 is also used to describe the operation of interconnected analog circuits that include coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115 described in greater detail below. As such, steps in method 1000 and indeed in steps of the other methods described below may not preclude the use of digital methodologies such as use of a microprocessor or microcontroller and associated algorithm to sense and control the operation of a bypass switch that may include coupling to coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115. Steps in method 1000 and indeed in steps of the other methods described below may not preclude the use of any number of implementations that combines both analog and digital methodologies.

As such, steps of method 1000, methods described below and decision steps such as decision steps 1005 and 1009 in particular may be made by virtue of a configuration of the analog circuits used below to implement coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115. The configuration may include calculation and selection of component values, types of components and the interconnections of components as part of the circuit design of coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115. The configuration may be based therefore, on the normal operating parameters where power sources 101 and/or power modules 130 are functioning correctly or to accommodate non-normal operating parameters of power systems 100 a/100 described above and in power systems described below. As such, the configuration with respect to the decision aspect of the decision steps described below may be responsive analog circuit wise to an event such as the breakdown or failure of a power module 103 and/or power source 101 so as to provide a bypass of the power module 103 and/or power source 101. In this regard, the configuration with respect to bypass circuit 115 and the other analog bypass circuit embodiments described below may be considered to be substantially activated and/or operated for most of the time such that the steps of method 1000 are performed responsive to the continuously changing operating parameters of power systems 100 a/100. The continuously changing operating parameters of power systems 100 a/100 for the bypass circuits 115 to be substantially activated most of the time may be where the power for the activation is provided from the string of serial connected power module 103 outputs, a module 103 and/or power source 101, a partial power from module 103 and/or power source 101 or power is supplied from an auxiliary power source (for example auxiliary power from auxiliary power circuit 162). As such, bypass circuit 115 and the other analog bypass circuit embodiments described below when considered as being substantially activated most of the time may not require sensors 125, controller 105 and associated algorithm to decide respectively in steps 1005/1007 to activate switch BP1 (ON) or to de-activate switch BP1 (OFF) in respective steps 1009/1011. A way therefore to enable a de-activation of bypass circuit 115 and the other analog bypass circuit embodiments described below from being substantially activated most of the time is for a controller to use driver circuitry 170 to apply a voltage to the gate of switch BP1 so that switch BP1 is OFF and/or de-activated thereby.

The configuration may also give the decision aspect of the decision steps described below so as to be responsive to an event such as a power module 103 and/or power source 101 reverting back to normal operation so as to remove a bypass of a power module 103 and/or power source 101.

The discussion that follows uses by way of non-limiting example, a power system such as power system 100 where power sources 101 are photovoltaic panels coupled to the inputs of power modules 103, and where the outputs of power modules 103 are coupled in series. The description that follows references power modules 103 but may equally apply to power sources 101. The configuration in this regard may take into account the voltages and currents present in the string of serially connected power module 103 outputs for example.

At step 1003, switch BP1 may be coupled across the outputs of a power module 103 where there may be a series string of power module 103 outputs. Provided the power modules 103 are functioning properly, switch BP1 is inactive (OFF). Alternatively, switch BP1 may also be coupled across the outputs of power sources 101.

At decision step 1005, a first bypass current conduction of diode PD1 may be an indication of power module 103 and/or power source 101 not functioning correctly. The indication according to the configuration may cause the subsequent activation of switch BP1 (step 1007) to be ON so that the output of a malfunctioning power module 103 is bypassed. Otherwise, switch BP1 remains OFF so that the bypass function of switch BP1 is inactive (step 1003).

A power module 103 not functioning correctly may be as a result of a panel becoming shaded or a component failure within power module 103 for example. As such, the flow of current (Istring) through an inactive power module 103 output may become restricted. As a result of restricted current flow, the voltage outputs of the other power modules 103 in the string may attempt to push the current through their outputs and through the inactive power module 103 output. The attempt at pushing current flow of current may be caused by an increase in voltage output of the other power modules 103, which may cause diode PD1 to become forward biased. Whereas when a normal operation of power module 103 exists, diode PD1 and the MOSFET of switch BP1 are reversed biased (the MOSFET is OFF). The forward biasing of diode PD1 may cause string current Istring to flow from anode to cathode of diode PD1 in the first bypass current conduction of diode PD1.

The first bypass current conduction of diode PD1 and forward voltage drop of diode PD1 is applied to the input of circuit 111, which may cause the oscillation of circuit 111. The output oscillations of circuit 111 may be fed back to the input of switch BP1 via coupling circuit 120. The output of coupling circuit 120 connects to the gate (g) of the MOSFET of switch BP1. The output of coupling circuit 120 applied to the gate of the MOSFET of switch BP1 may be sufficient to cause the MOSFET of switch BP1 to switch ON so that switch BP1 is activated at step 1007.

At decision step 1009, if inactive power module 103 remains inactive, then the MOSFET of switch BP1 remains ON so that switch BP1 remains activated at step 1007. However, when power module 103 starts to become active, both the MOSFET and diode PD1 of switch BP1 become reverse biased. Power module 103 may become active because a panel coupled to power module may become unshaded, for example. The reverse bias voltages of both the MOSFET and diode PD1 of switch BP1 applied to the input of circuit 111 at terminals A and B may cause the ceasing of the oscillations of circuit 111. The output oscillations of circuit 111 ceasing fed back to the input of switch BP1 via coupling circuit 120 may be sufficient to cause the MOSFET of switch BP1 to switch OFF, so that switch BP1 is de-activated at step 1011. The reduction of voltage applied to the gate of the MOSFET may cause the MOSFET to turn OFF. Alternatively, sensors 125 under control of controller 105 or some other controller may sense the reverse bias voltages of both the MOSFET and diode PD1 of switch BP1. As a result of the reverse biases being sensed, switch BP1 may be switched OFF and power from a driver circuitry may be allowed to be resupplied to the switches of power module 103 to allow power module 103 to function as normal. With the power modules 103 functioning normally, switch BP1 is now inactive (OFF) but still coupled at terminals A and B (step 1003).

Reference is now made to FIG. 1I, which shows further details of coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115, according to illustrative embodiments. Coupling circuit 120 may include biasing and driver circuitry 170 that has an output coupled to a first end of resistor R3 and a first end of resistor R4. The second end of resistor R3 may couple to the cathode of diode D1, a first end of capacitor C3 and the gate (g) of switch Q3 via switch wire C11. A second end of resistor R4 may couple to a second end of capacitor C3 and terminal B. The second end of capacitor C3 may couple to a first end of inductor L3 and a second end of inductor L3 may couple to the anode of diode D1. The gate (g) of switch BP1 may couple to the first ends of resistors R3 and R4. The drain (d) of switch BP1 may couple to the cathode of diode PD1 at terminal B to give a return connection RET1. The anode of diode PD1 may couple to the source (s) of switch BP1, the anode of diode BD2 that belongs to switch Q3 and the source (s) of switch Q3. The drain (d) of switch Q3 may couple the cathode of diode BD2 and a first end of inductor L1 of circuit 111. Switch BP1 may be a metal oxide semiconductor field effect transistor (MOSFET), which may include diode PD1 or which may not include diode. Similarly switches Q1, Q2 and Q3 may be MOSFETs, which include a diode like diode BD2 or which may not include a diode.

In circuit 111, a second end of inductor L1 may couple to the drains (d) of switches Q1 and Q2. The sources (s) of Q1 and Q2 may be coupled together to give a return connection RET2. A first end of resistor R1 may couple between the gate of switch Q1 and the source (s) of switch Q1. A first end of resistor R2 may couple between the gate of switch Q2 and the source (s) of switch Q2. The gate (g) of switch Q1 may couple to a first end of capacitor C2. A second end of capacitor C2 may couple to a first end of inductor L2 and a first end of capacitor C1. A second end of inductor L2 may provide return connection RET3. A second end of capacitor C1 may couple to the gate of switch Q2. Return connections RET1, RET2 and RET3 may couple together to form a return path that may be separate to terminal B at the source(s) of switch BP1. Separation between the return path and terminal B in bypass circuit 115, along with the integration of bypass circuit 115 across the output of a power module 103, may be achieved by disposing switch Q3 and diode BD2 between terminal B and inductor L1. Switches BP1, Q2 and Q3 may be metal oxide semiconductor field effect transistors (MOSFETs) and switch Q1 may be a junction field effect transistor (JFET).

In some embodiments, inductors L1, L2 and L3 may be mutually coupled on the same magnetic core. In effect, the coupling between inductor L1 to L2 and then inductor L2 to L3 provide a possible function of coupling unit 120 a shown in FIG. 1G, which allows a coupling between the output of circuit 111 and coupling circuit 120. Therefore, the output of circuit 111 across inductor L1 may be coupled back to the input of coupling circuit 120 via the mutual inductance between inductor L1 and inductor L3 and also coupled to inductor L2 via the mutual coupling between inductor L1 and inductor L2. The mutual inductance between inductor L1 and inductor L2 and voltages induced into inductor L2 drive the gates (g) of switches Q1 and Q2 via the coupling of respective capacitors C2 and C1. The mutual coupling between inductor L1 and inductors L2 and L3 may be such that inductors L2 and L3 have a greater number of turns across the common magnetic core than inductor L1 does, so the voltages induced into inductors L2 and L3 are greater by virtue of the transformer equations:

$\frac{{VL}\; 1}{{VL}\; 2} = \frac{{NL}\; 1}{{NL}\; 2}$ and $\frac{{VL}\; 1}{{VL}\; 3} = \frac{{NL}\; 1}{{NL}\; 3}$

Where VL1, VL2 and VL3 are the respective voltages of inductors L1, L2 and L3, where NL1, NL2 and NL3 are the respective number of turns of inductors L1, L2 and L3.

The greater voltages induced into inductors L2 and L3 by virtue of the greater number of turns NL2 and NL3 may allow for operation of switches BP1, Q1, Q2 and Q3, whereas without the greater voltages induced, switches BP1, Q1, Q2 and Q3 might not be able to operate otherwise.

Inductor L2 and capacitors C1 and C2 in circuit 111 function as a Colpitts oscillator.

The frequency of oscillation given by:

$f_{o} = \frac{1}{2\pi \sqrt{L_{2}\left( \frac{C_{1}C_{2}}{C_{1} + C_{2}} \right)}}$

Inductors L1, L2, L3, capacitors C1 and C2 may be chosen so that a frequency of oscillation for circuit 111 may be between 1 and 4 Kilohertz (KHz). The low frequency of oscillation of circuit 111 may therefore, provide low losses in the switching of Q1, Q2 and Q3. Alternatively, capacitor C1 may be replaced with another inductor so that circuit 111 may be implemented as a Hartley oscillator. Inductor L3 of coupling circuit 120 may be built on the same core as inductors L1 and L2 in circuit 111, diode D1 may be used to rectify voltages induced on inductor L3 that may be by virtue of the mutual coupling between inductor L3 to inductors L1 and L2 of circuit 111. The rectified pulses may drive the voltage (Vgs) between gate (g) and source (s) of the MOSFET of switch BP1 to turn switch BP1 ON for continuous conduction of switch BP1 at step 1007.

Reference is now made again to FIG. 1F with method 1000 applied to the further details of coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115 shown in FIG. 1G, according to illustrative embodiments. At step 1003, switch BP1 may be coupled across the outputs of a power module 103 where there may be a series string of power module 103 outputs. Switch BP1 is not active in step 1003.

At decision step 1005, specifically a first bypass current conduction of diode PD1 may be an indication of power module 103 and/or power source 101 not functioning correctly. Consequently, the flow of current (Istring) through an inactive power module 103 output may become restricted. As a result of restricted current flow, the voltage outputs of the other power modules 103 in the string may attempt to push the current through their outputs and through the inactive power module 103 output. The attempt at pushing current flow of current may be caused by an increase in voltage output of the other power modules 103, which may cause diode PD1 to become forward biased so that a first bypass current conduction of current occurs through diode PD1. Diode PD1 becoming forward bias also results in diode BD2 also being forward biased. The forward biasing of diode BD2 allows the utilization of circuit 111 to initiate a continuous operation of switch BP1. Detailed description of the operation of circuit 111 is described later on in the descriptions which follow.

At step 1007, circuit 111 may initiate the continuous operation of switch BP1. As soon as diode PD1 conducts, Q2 and/or Q1 may be ON, and circuit 111 may maintain the continuous operation of switch BP1 so that the MOSFET of switch BP1 is ON such that the voltage (Vds) between drain (d) and source (s) of switch BP1 remains low, e.g., from about 10 millivolts (mV) substantially up to 200 mV. A comparison between Vds of 10 mV of switch BP1 and a forward voltage drop 0.7V of a bypass diode to bypass a string current Istring of 25 Amperes gives bypass power losses of 0.25 Watts and 17.5 Watts, respectively. As such, operation of switch BP1 in bypass circuit 115 and other bypass circuit embodiments described below provide efficient bypass circuits that may allow the bypassing power sources and/or other circuit elements without incurring significant losses by the bypass itself. Bypassing power sources and/or other circuit elements without incurring significant losses may be significant when compared to other ways of providing a bypass that may include the use of bypass diodes, for example.

At step 1007, return connections RET1, RET2 and RET3 may couple together to form a return path that may be a separate return path to that provided at terminal B at the source (s) of switch BP1. Separation between the return path and terminal B between coupling circuit 120 and circuit 111 may be by switch Q3 and diode BD2. Consequently, oscillations of circuit 111 may build on the drains of switches Q2 and/or Q1, while the return path for the oscillations may be provided on the sources(s) of switches Q2 and/or Q1.

At decision step 1009, if inactive power module 103 remains inactive, then the MOSFET of switch BP1 remains ON so that switch BP1 remains activated at step 1007. At decision step 1009, if switch BP1 remains activated at step 1007, power from driver circuitry 170 may be isolated from being supplied to the inactive power module 103. However, when power module 103 starts to become active, for example when a panel becomes unshaded that may be sensed by sensors 125, power from driver circuitry 170 may be allowed to be resupplied to the switches of power module 103 to allow the functioning of power module 103. Both the MOSFET and diode PD1 of switch BP1 and diode BD2 at this point may become reverse biased. The reverse bias voltages of both the MOSFET and diode PD1 of switch BP1 applied to the input of circuit 111 at the anode of diode BD2 may cause the ceasing of the oscillations of circuit 111. The output oscillations of circuit 111 ceasing when feedback to the input of switch BP1 via coupling circuit 120 may be sufficient to cause the MOSFET of switch BP1 to switch OFF, so that switch BP1 is de-activated at step 1011. Alternatively, sensors 125 under control of controller 105 or some other controller may sense the reverse bias voltages of both the MOSFET and diode PD1 of switch BP1. As a result of the reverse biases being sensed, switch BP1 may be switched OFF and power from driver circuitry 170 may be allowed to be resupplied to the switches of power module 103 to allow power module 103 to function as normal. The reduction of voltage applied to the gate of the MOSFET of switch BP1 causes the MOSFET to turn OFF. With the power modules 103 functioning normally switch BP1 is now inactive (OFF) but still coupled at terminals A and B (step 1003).

Operation of Circuit 111

Reference is now made to FIG. 1J and FIG. 1K which show, respectively, circuit 111 and a flow chart of step 1007 in greater detail, according to illustrative embodiments. Step 1007 occurs if a power module 103 does not work, so that switch BP1 draws the current in the series string (Istring) in a path around the output of an inactive power module 103. Circuit 111 may be the same as described with regard to FIG. 1G, and may be coupled to bypass switch BP1. Switches Q1 and Q2 may be biased with resistors R1 and R2 respectively. In operation of circuit 111 when switch BP1 is OFF and a power module 103 is working correctly at step 1011, switch Q3 and diode BD2 may block leakage current through bypass switch BP1 and block reverse voltage across bypass switch BP1 when the voltage at terminal A may be much greater than the voltage at terminal B. Conversely when a power module 103 is not working at step 1007, switch Q3 is operated by the rectified output provided by diode D1 so that diode BD2 is bypassed by switch Q3 when switch Q3 may be ON. Switch Q3 OFF during step 1007 provides a block of leakage current through bypass switch BP1. Switch Q3 being ON may additionally compensate for any drop in voltage across terminals A and B as a result of switch BP1 being turned ON and being maintained as ON during step 1007 so as to give headroom for circuit 111 to oscillate. Switch Q3 and its operation is ignored and is to be considered to be ON, in order to simplify the following description.

In decision step 1203, if a low amount of power is being produced by a power source 101 and respective power module 103 compared to other power sources 101 and respective power modules 103 in a series string of power module 103 outputs, a first bypass current conduction may therefore be through diode PD1. Similarly, if the power source 101 and respective power module 103 has a failure the first bypass current conduction may also be through diode PD1.

At decision step 1205 the first bypass current conduction may induce a voltage VL1 across inductor L1 since diode BD2 is similarly forward biased as diode PD1. At step 1205, bypass switch BP1 may be positively biased with respect to output voltage (VAB) of power module 103. Bypass switch BP1 being positively biased with respect to output voltage (VAB) of power module 103 may be a result of power module 103 not functioning. The first bypass current conduction to provide the bypass of current through bypass switch BP1 may therefore be through diode PD1, followed by the conduction of inductor L1 via diode BD2 and then by the conduction of inductor L1 by use of switch Q1 in a first stage of operation of bypass switch BP1.

An example of the low amount of power may be when power sources 101 may be photovoltaic panels that have just begun to be illuminated (e.g., at dawn) or when a photovoltaic panel may be substantially and/or partially shaded. Shading may reduce power generated by a power source 101 (e.g., reducing the power generated by, for example, 20%, 50% or even close to 100% of the power generated by an unshaded power source). If enough power may be produced by power sources 101 in decision step 1203, circuit 111 may continue to oscillate with an initial use of switch Q1 for a number of times according to the steps of 1209-1217 described below as part of the first stage of operation of switch BP1 until the second stage of operation where switch Q2 and/or Q1 are used. Q1 may be implemented using a junction field effect transistor (JFET) rather than a MOSFET since a JFET compared to a MOSFET may have a lower bias input current compared to a MOSFET and a JFET may conduct between source (s) and drain (d) when the voltage between gate (g) and source (Vgs) is substantially zero. Q1 may also be implemented using a depletion mode FET.

Following on from the first stage with the use of Q1, steps 1209-1217 are implemented with the use of switch Q2 and/or switch Q1 as part of a second stage of operation of switch BP1. The principal of operation for both the first stage and the second stage is that inductor L1 is mutually coupled to inductors L3 and L2 when current flows through inductor L1. The mutual coupling is such that when current flows through inductor L1, current flows in inductor L2 and induces a voltage VL2 into inductor L2. Voltage VL2 may charge the gate (g) of switches Q2 and/or switch Q1 (step 1209) via capacitors C1 and/or C2. The charging of the gate (g) of Q2 and/or switch Q1 may cause switch Q2 and/or switch Q1 to start to conduct current between source (s) and drain (d) of switch Q2 and/or switch Q1 so that Q2 and/or switch Q1 is ON (step 1211) for a time period ton.

The energy induced into inductor L1 during ton may be discharged by a time constant τ [L1]

τ[L1]=L1×Req

where Req may be the equivalent resistance that includes resistors R2 and/or R1 and the respective resistances (Rds) between drain (d) and source (s) when switch Q2 and/or Q1 may be ON. The value of respective resistances (Rds) between drain (d) and source (s) when switch Q2 and/or Q1 may be ON may be derived from manufacturer data sheets for the particular devices chosen for switches Q2 and Q1 as part of the design of circuit 111. Discharge of inductor L1 (step 1213) may continue in decision step 1215 until voltage VL2 of inductor L2 in decision step 1215 drops below the threshold voltage of Q2 and/or switch Q1 which makes Q2 and/or switch Q1 switch OFF (step 1217) for a time period toff. Q2 and/or switch Q1 drain (d) voltage then may begin to increase by the ratio:

$\frac{ton}{t\; {off} \times {VAB}}$

so that voltage may again increase on L2 for a time defined by a time constant τ [L2], after which switch Q2 and/or switch Q1 conducts again (step 1209), which may create the oscillation of circuit 111. The time constant τ [L2] may be given by:

τ[L2]=√{square root over (L2×Ceq)}

where Ceq may be the equivalent capacitance that includes capacitors C1 and C2 and the parasitic capacitances of switches Q2 and/or Q1. Parasitic capacitances of switches Q2 and/or Q1 may be derived from manufacturer data sheets for the particular devices chosen for switches Q2 and Q1 as part of the design of circuit 111. Parasitic capacitances of switches Q2 and/or Q1 may or may not be a significant factor in the desired value of time constant τ [L2]. Inductor L1 coupled to inductor L3 may cause a voltage to be induced in inductor L3 when current flows through inductor L1. The voltage induced into inductor L3 may be rectified by diode D1. The rectified voltage of diode D1 may be applied to the gate (g) of bypass switch BP1 via bias resistors R3 and R4, which may turn bypass switch BP1 to be ON (step 1007).

Reference is now made to FIG. 1L, which shows transient traces 181 of measurements made on a working design of bypass circuit 115, according to illustrative embodiments. Transient traces 181 show the effects of switch BP1 in a transition from being OFF to being ON. The transient traces further show the entry into steady state condition where switch BP1 is ON at step 1007. The steady state condition may be where switch BP1 is ON at step 1007 and may be an example of an inherent stabilization of bypass circuit 115. The inherent stabilization of bypass circuit 115 may be established during the second stage of operation of switch BP1 at step 1007. The transition shows the effect of the operation of switch BP1: in the first bypass, current conduction through diode PD1, followed by switch Q1 being operated in the first stage of operation, followed by switch Q2 and/or switch Q1 being operated in the second stage of operation of switch BP1.

Trace 184 shows the transient behavior of the voltage (Vgs) between gate (g) and source (s) of the MOSFET of switch BP1. Trace portion 184 a shows when a power module 103 may be functioning incorrectly so that switch BP1 and/or diode PD1 are forward biased and string current Istring flows through diode PD1. Trace portion 184 a is when a module 103 and/power source 101 are not functioning correctly at step 1203. Trace portion 184 a shows how the gate (g) source (s) voltage Vgs of switch BP1 begins to fluctuate as a result of the first bypass current conduction through diodes PD1 and BD2 at step 1205. Gate (g) voltage of the MOSFET of switch BP1 is derived from the rectified voltage (from diode D1) induced in inductor L3 which is mutually coupled to inductor L1. The rectified voltage (from diode D1) also drives the gate of switch Q3 so that after the first bypass current conduction of diodes PD1 and BD2 at step 1205, current flow through inductor L1 is through both the source (s) and drain (d) of Q3 and/or diode BD2. Beyond trace portion 184 a is shown the steady continued rise of the gate (g) source (s) voltage Vgs of switch BP1 of the first stage by use of switch Q1 and then by the second stage by use of switches Q1 and/or Q2. The fluctuation of gate (g) source (s) voltage (Vgs) of switch BP1 because of the first bypass current conduction through diodes PD1 and BD2 at step 1205 and the use of switches Q1 and/or Q2 in steps 1209-1217 shows a steady buildup of Vgs during the first stage. As such, both the initial fluctuation of Vgs and the steady buildup of Vgs during the first stage demonstrates a positive feedback loop between the output of circuit 111 back to the input of circuit 111 via coupling circuit 120. The positive feedback loop is therefore responsive to the output of power modules 103 and/or power sources 101 in order to establish that Vgs is sufficient to turn switch BP1 ON, to thereby provide a bypass across terminals A and B.

Trace portion 180 shows the current flow of inductor L1. The principal of operation for the first bypass current conduction through diodes PD1 and BD2, the first stage by use of switch Q1 and the second stage by use of switches Q1 and/or Q2 is that inductor L1 is mutually coupled to inductors L3 and L2 when current flows through inductor L1. The mutual coupling is such that when current flows through inductor L1, current flows in inductor L2 and induces a voltage VL2 into inductor L2. Voltage VL2 may charge the gates (g) of switches Q2 and/or switch Q1 (step 1209) via capacitors C1 and/or C2. The charging of the gate (g) of Q2 and/or switch Q1 may cause switch Q2 and/or switch Q1 to start to conduct current between source (s) and drain (d) of switch Q2 and/or switch Q1 so that Q2 and/or switch Q1 is ON (step 1211) for a time period ton. Discharge of inductor L1 (step 1213) may continue in decision step 1215 until voltage VL2 of inductor L2 in decision step 1215 drops below the threshold voltage of Q2 and/or switch Q1 which makes Q2 and/or switch Q1 switch OFF (step 1217) for a time period toff. The transient nature of the ON and OFF periods, ton and toff for switches Q1 and/or switch Q2 are shown by trace portion 180. The steady state at step 1007 for traces 180 and 184 are shown in the descriptions of the figures that follow.

Inherent stabilization of bypass circuit 115 may be established during the second stage of operation of switch BP1 by virtue of the feedback loop established from the output of circuit 111 back to the input of circuit 111 via coupling circuit 120 being responsive to the output of power modules 103 and/or power sources 101. As such, the steady continued rise of the gate (g) source (s) voltage Vgs of switch BP1 is only allowed to rise to a certain level of voltage so as to maintain switch BP1 to be ON. The feedback loop during the second stage therefore is a negative feedback loop. The negative feedback loop may be responsive to the output of power modules 103 and/or power sources 101 establishes and maintains the activation of switch BP1 to be ON continuously at step 1007 until a power module 103 and/or power source 103 becomes active once more at step 1009. Switch BP1 at step 1007 is forward biased with respect to terminals A and B during bypass mode and the voltage applied to gate (g) of switch BP1 is such that switch BP1 is continuously ON for the time period that the non-functioning power module 103 is required to be bypassed. Likewise, the feedback loop responsive to the output of power modules 103 and/or power sources 101 establishes and maintains the deactivation of switch BP1 to be OFF continuously at step 1011 until a power module 103 and/or power source 103 becomes once again inactive. Switch BP1 is reverse biased with respect to terminals A and B during non-bypass mode and the voltage applied to gate (g) of switch BP1 is such that switch BP1 is continuously OFF for the time period that the functioning power module 103 is required not to be bypassed at step 1011.

Inherent stabilization may therefore occur when switch BP1 may be ON at step 1007, so that as its drain to source voltage Vds falls, the gate (g) to source (s) voltage Vgs also falls. Similarly, stabilization of bypass circuit 115 may be established when switch BP1 may be OFF at step 1011, so that as its drain (d) to source (s) voltage Vds rises, the gate (g) to source (s) voltage Vgs also rises.

Reference is now made to FIGS. 1M and 1N, which show steady state measurement traces 182 and 180 made on bypass circuit 115, according to illustrative embodiments. The measurement traces shown are for when a non-functioning power module 103 as part of a series connection of power modules 103 outputs is not functioning correctly and needs to be bypassed by switch BP1 for a string current (Istring) operating up to a maximum of 25 Amperes. The measurement traces demonstrate that switch BP1 is forward biased with respect to terminals A and B during bypass mode and the gate (g) of switch BP1 is such that switch BP1 is continuously ON for the time period that the non-functioning power module 103 is required to be bypassed.

Reference is now made to FIG. 1M, which shows an oscilloscope trace 182 of the measured steady state traces 184, 186 and 188, according to illustrative embodiments. Trace 184 may be the measured gate (g) source (s) voltage Vgs of switch BP1 when switch BP1 is used to bypass a power module 103 output (step 1007) when a power module 103 does not work. According to trace 184, it can be seen that the measured gate (g) source (s) voltage Vgs of switch BP1 may stay substantially constant at approximately 5.8 volts, which makes bypass switch BP1 to be ON for the time periods ton and toff. Time periods ton and toff refer respectively to when switches Q2 and/or Q1 are ON (step 1211) and OFF (step 1217). Trace 186 shows the measured voltage across inductor L3 which begins at about minus 1.3 volts, rises to a peak of approximately 13 volts, rapidly drops to minus 7.8 volts and then returns back to minus 1.3 volts for a time period of toff (step 1217). The voltage across inductor L3 then remains at about minus 1.3 volts for a time period ton (step 1211). Trace 188 is the measured voltage between drain (d) source (s) voltage Vds of switch Q2, which begins at minus 1.3 volts and rises to a peak of approximately 3.8 volts and returns back to minus 1.3 volts for a period of toff (step 1217). Vds then remains at minus 1.3 volts for time period ton (step 1211).

Reference is now made to FIG. 1N, which shows an oscilloscope trace 180 of the measured steady state current in inductor L1, according to illustrative embodiments. The steady state current in inductor L1 is for when switch BP1 is activated to be ON (step 1007). The ramp portion 180 a of trace 180 begins at a current level through inductor L1 beginning at −350 micro-Amperes (μA) and carries on increasing for a time period ton (step 1211) where the current may reach 77 milli-Amperes (mA). Once the current in inductor L1 reaches 77 mA, the ramp drops back down to −350 μA for a time period toff (step 1217). At the end of the time period toff (step 1217), the ramp portion 180 a of trace 180 begins once again where the current through inductor L1 reaches 77 mA for the time period ton (step 1211). For both FIGS. 1L and 1M ton (step 1211) may be 240 μseconds and toff may be 20 μseconds. The frequency of oscillation of circuit 111 may be the inverse of 260 μseconds which may be 3.85 KiloHertz (KHz).

Utilization of a first bypass current conduction through diode PD1, switch Q1 in the first stage of operation, Q2 and/or Q1 in the second stage of switch BP1 may therefore give a continuous operation of a bypass of the output of a non-functioning power module 103. The continuous operation of bypass switch BP1 to carry a wide range of currents (e.g. substantially zero to 30 amperes of string current (Istring)) where the conduction of the bypass circuit 115 may be, for example, 10 mV-200 mV compared to 0.7V of bypass diode BPD1. Additionally, operation of bypass circuit 115 may be utilized as part of a ‘wake-up’ of power system 100 when power sources 101 (e.g., photovoltaic (PV) generators) begin to produce a partial power or when PV generators may be completely shaded. Bypass circuit 115 may then utilize power from auxiliary power circuit 162 and/or the conduction of diode PD1 at step 1205 followed by the first and second stages of operation of bypass 115 as described above in steps 1209-1217 to bypass a power source and/or a PV generator.

Reference is now made to FIG. 1O, which shows a bypass circuit 115 a, according to illustrative embodiments. The sources (s) of switches described herein are referred to as first terminals, the drains (d) are referred to second terminals and the gates (g) are referred to as third terminals. An output of charge pump 130 may be coupled to the input of switch BP1 across the first terminal and third terminal of switch BP1. The first and second terminals of switch BP1 connect to the input of charge pump 130. The anode of diode PD1 connects to the first terminal of switch BP1 and the cathode of diode PD1 connects to the second terminal of switch BP1. Nodes A and B are provided respectfully at the second and first terminals of switch BP1. Charge pump 130 may be configured to receive a very low voltage (e.g., tens or hundreds of millivolts) at its input, and output a substantially larger voltage (e.g., several volts). To enable the substantially larger voltage, charge pump 130 may include several conversion stages. Variations of illustrative circuits for charge pump 130 may be found in “0.18-V Input Charge Pump with Forward Body Biasing in Startup Circuit using 65 nm CMOS” (P. H. Chen et. al., ©IEEE 2010), “Low voltage integrated charge pump circuits for energy harvesting applications” (W. P. M. Randhika Pathirana, 2014), which may be used as or as part of charge pump 130.

Reference is now made to FIG. 1P, which shows a bypass circuit 115 b, according to illustrative embodiments. Bypass circuit is the same as bypass circuit 115 a but with a first terminal of switch Q3 connected to terminal B and a second terminal connected to the input of charge pump 130. The third terminal of switch Q3 connects to the third terminal of switch BP1.

Reference is now made again to method 1000 shown in FIG. 1H and to FIGS. 1O and 1P, according to illustrative embodiments. At step 1003, switch BP1 may be coupled across the outputs of a power module 103 where there may be a series string of power module 103 outputs. Provided the power modules 103 are functioning properly, switch BP1 is inactive (OFF). Alternatively, switch BP1 may also be coupled across the outputs of power sources 101.

At decision step 1005, a first bypass current conduction of diode PD1 may be an indication of power module 103 and/or power source 101 not functioning correctly. The indication according to the configuration may cause the subsequent activation of switch BP1 (step 1007) to be ON so that the output of a malfunctioning power module 103 is bypassed. Otherwise, switch BP1 remains OFF so that the bypass function of switch BP1 is inactive (step 1003). Whereas when a normal operation of power module 103 exists, diode PD1 and the MOSFET of switch BP1 are reversed biased (the MOSFET is OFF).

The forward biasing of diode PD1 may cause current Istring to flow from anode to cathode of diode PD1 in a first bypass current conduction of diode PD1.

The first bypass current conduction of diode PD1 and forward volt drop of diode PD1 is applied to the input of charge pump circuit 130, which may cause the buildup of the voltage output of charge pump circuit 130. The output voltage of charge pump circuit 130 may be fed back to the input of switch BP1. The output voltage of charge pump circuit 130 applied to the gate of the MOSFET of switch BP1 may be sufficient to cause the MOSFET of switch BP1 to switch ON so that switch BP1 is activated at step 1007. Conversely, with respect to the use of bypass circuit 115 b when a power module 103 is not working at step 1007, switch Q3 is operated by the output of charge pump 130 so that diode BD2 is bypassed by switch Q3 when switch Q3 may be ON. Switch Q3 OFF during step 1007 provides a block of leakage current through bypass switch BP1. Switch Q3 being ON, additionally compensates for any drop-in voltage across terminals A and B as a result of switch BP1 being turned ON and being maintained as ON during step 1007 so as to may be give headroom for charge pump 130 to function.

At decision step 1009, if inactive power module 103 remains inactive then the MOSFET of switch BP1 remains ON so that switch BP1 remains activated at step 1007. However, when power module 103 starts to become active both the MOSFET and diode PD1 of switch BP1 become reverse biased. Power module 103 may become active because a panel coupled to power module may become un-shaded for example. The reverse bias voltages of both the MOSFET and diode PD1 of switch BP1 applied to the input of charge pump circuit 130 at terminals A and B may cause the decreasing of the output voltage of charge pump circuit 130 and/or a reverse voltage output of charge pump circuit 130. The decreasing of the output voltage of charge pump circuit 130 and/or a reverse voltage output of charge pump circuit 130 applied to the gate (g) of switch BP1 may be sufficient to cause the MOSFET of switch BP1 to switch OFF so that switch BP1 is de-activated at step 1011. The reduction of voltage applied to the gate of the MOSFET therefore may cause the MOSFET to turn OFF. Alternatively, sensors 125 under control of controller 105 or some other controller may sense the reverse bias voltages of both the MOSFET and diode PD1 of switch BP1. As a result of the reverse biases being sensed, switch BP1 may be switched OFF and power from driver circuitry such as driver circuitry 170 for example, may be allowed to be resupplied to the switches of power module 103 to allow power module 103 to function as normal. With the power modules 103 functioning normally, switch BP1 is now inactive (OFF) but still coupled at terminals A and B (step 1003).

Reference is now made to FIG. 1Q, which shows further details for a bypass circuit 115 c, according to illustrative embodiments. Coupling 120 circuit may include resistor R5, capacitor C4, resistor R6, diode D2 and inductor L5. Resistor R5 may have a first end coupled to the gate (g) of switch BP1. Resistor R5 may have a second end coupled to terminal B. Capacitor C4 may be coupled across resistor R5. A first end of capacitor C4 may be coupled to terminal B and to a first end of inductor L5. A second end of inductor L5 may be coupled to the anode of diode D2. A second end of capacitor C4 may be coupled to one end of resistor R6. A second end of resistor R6 may be coupled to the cathode of diode D2.

The sources (s) of switches described herein are referred to as first terminals, the drains (d) are referred to second terminals and the gates (g) are referred to as third terminals. Circuit 111 a may include the second terminals of switch BP1 may couple to the second terminals of switch Q4 and the cathode of diode PD1 of switch BP1. The anode of diode PD1 may couple to terminal B, the voltage (Vin1) input of charge pump 130 and a first end of inductor L4. The second end of inductor L4 may couple to the first terminals of switch Q4. The third terminals of switch Q4 may couple to the voltage output (Vout2) of PWM 132. The output voltage (Vout1) of charge pump 130 may couple to the anode of diode D5. The cathode of diode D5 may couple to the cathode of diode D4 and the input voltage (Vin2) of pulse width modulator (PWM) 132. The anode of diode D4 may couple to the cathode of diode D3 and a first end of capacitor C5. The second end of capacitor C5 may couple to a first end of inductor L6 and provide return connection RET6. The second end of inductor L6 may couple to the anode of diode D3. Both PWM 132 and charge pump 130 provide respective return paths RET5 and RET6. Return paths RET4, RET5 and RET6 may be coupled together. Inductors L4, L5 and L6 may be all mutually coupled together on the same core CR1, as such the output of circuit 111 a on inductor L4 may be coupled back to the input of coupling circuit 120 on inductor L5. Charge pump 130 may be realized by a Switched-Capacitor Voltage Converter MAX1680C/D® (Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, Calif. USA), which may double input voltage (Vin1) on output Vout1. PWM 132 may be realized by use of the LTC®6992 a silicon circuit with an analog voltage-controlled pulse width modulation (PWM) capability by Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, Calif., USA.

Reference is now again made to FIG. 1Q and again to FIG. 1H, which shows a flowchart of method 1000, according to illustrative embodiments. Switch BP1 may couple (step 1003) across the outputs of power modules 103 where there may be a series string of power module 103 outputs. At decision step 1005, if a power module 103 does not work, switch BP1 draws the current in the series string (Istring) in a path around from the output of an inactive power module 103 (step 1007).

At decision step 1005, a first bypass current conduction of diode PD1 may be an indication of power module 103 and/or power source 101 not functioning correctly. Methods described below and decision steps in particular assume that so called ‘decisions’ are made by virtue of a configuration of the analog circuits used below to implement coupling circuit 120, switch BP1 and circuit 111 a in bypass circuit 115 c. As such steps in method 1000 and indeed in steps of the other methods described below may not preclude the use of digital methodologies such as use of a microprocessor or microcontroller and associated algorithm to sense and control the operation of a bypass switch which may include coupling to circuit 120, switch BP1 and circuit 111 a in bypass circuit 115. Steps in method 1000 and indeed in steps of the other methods described below may not preclude the use of any number of implementations that combines both analog and digital methodologies.

As with analog circuits, the configuration may include calculation and selection of component values, types of components and the interconnections of components as part of the circuit design of coupling circuit 120, switch BP1 and circuit 111 a in bypass circuit 115 c. The configuration may be based therefore, on the normal operating parameters or non-normal operating parameters of power systems 100 a/100 described above and in power systems described below. As such the configuration with respect to the decision aspect of the decision steps described below may be responsive analog circuit wise to an event such as the breakdown or failure of a power module 103 and/or power source 101, so as to provide a bypass of the power module 103 and/or power source 101.

The configuration may also give the decision aspect of the decision steps described below so as to be responsive to an event such as a power module 103 and/or power source 101 reverting back to normal operation so as to remove a bypass of a power module 103 and/or power source 101. The indication according to the configuration may cause the subsequent activation of switch BP1 (step 1007) to be ON, so that the output of a malfunctioning power module 103 is bypassed. Otherwise, switch BP1 remains OFF so that the bypass function of switch BP1 is inactive (step 1003).

The attempt at pushing current flow of current through a non-functioning power module 103 may be caused by an increase in voltage output of the other power modules 103, which may cause diode PD1 to become forward biased. Whereas when a normal operation of power module 103 exists, diode PD1 and the MOSFET of switch BP1 are reversed biased (the MOSFET is OFF). The forward biasing of diode PD1 may cause current Istring to flow from anode to cathode of diode PD1 in a first bypass current conduction of diode PD1. The forward biasing of diode PD1, similarly cause the forward biasing of switch Q4. The first bypass current conduction of diode PD1 and the forward voltage of diode PD1 may be applied to the input of circuit 111 a, which may cause the oscillation of circuit 111 a. The output oscillations of circuit 111 a may be fed back to the input of switch BP1 via coupling circuit 120. The output of coupling circuit 120 connects to the gate of the MOSFET of switch BP1. The output of coupling circuit 120 applied to the gate of the MOSFET of switch BP1 may be sufficient to cause the MOSFET of switch BP1 to switch ON, so that switch BP1 is activated at step 1007. In step 1007, circuit 111 a initiates the continuous operation of switch BP1 as soon as the diode PD1 conducts, and later by use of switch Q4 to maintain the continuous operation of switch BP1 such that the voltage (Vds) between drain (d) and source (s) of switch BP1 remains low at substantially up to 100 milli-volts (mv).

At decision step 1009, if inactive power module 103 remains inactive, then the MOSFET of switch BP1 remains ON so that switch BP1 remains activated at step 1007. However, when power module 103 starts to become active, both the MOSFET and diode PD1 of switch BP1 and switch Q4 become reverse biased. Power module 103 may become active because a panel coupled to power module may become un-shaded for example. The reverse bias voltages of both the MOSFET and diode PD1 of switch BP1 and switch Q4 applied to the input of circuit 111 a at terminals A and B may cause the ceasing of the oscillations of circuit 111 a. The output oscillations of circuit 111 a ceasing fed back to the input of switch BP1 via coupling circuit 120 may be sufficient to cause the MOSFET of switch BP1 to switch OFF so that switch BP1 is de-activated at step 1011. The reduction of voltage applied to the gate of the MOSFET causes the MOSFET to turn OFF. Alternatively, sensors 125 under control of controller 105 or some other controller may sense the reverse bias voltages of both the MOSFET and diode PD1 of switch BP1. As a result of the reverse biases being sensed, switch BP1 may be switched OFF and power from driver circuitry such as driver circuitry 170 for example, may be allowed to be resupplied to the switches of power module 103 to allow power module 103 to function as normal. With the power modules 103 functioning normally switch BP1 is now inactive (OFF) but still coupled at terminals A and B (step 1003).

Operation of Circuit 111 a

Reference is now made again to FIG. 1Q and FIG. 1R, which show respectively bypass 115 c and a flow chart showing further details of step 1007, according to illustrative embodiments. Step 1007 occurs if a power module 103 does not work, so that switch BP1 draws the current in the series string (Istring) in a path around the output of an inactive power module 103 in a series string of power module 103 outputs. In operation of circuit 111 a, a switch and its diode may be incorporated into charge pump 130 or may be attached thereto. The switch (not shown but similar in function to switch Q3 and diode BD2 in FIG. 1I) may block leakage current through bypass switch BP1 and block reverse voltage across bypass switch BP1. The blocking of reverse voltage may be when the voltage at terminal A may be much greater than the voltage at terminal B such a situation may be when the power module 103 is operating correctly at step 1003. The switch and its operation may be ignored for ease of the following discussion and is considered to be ON.

In decision step 1303, the continuous operation of switch BP1 in bypass of a power module 103 output begins as soon as the diode PD1 of switch BP1 conducts in a first bypass current conduction. After the first bypass current conduction, a first stage of the continuous operation of switch BP1 may be established primarily by use of charge pump 130, PWM 132 and switch Q4. After several possible cycles as described in the steps which follow by use of charge pump 130, PWM 132 and switch Q4, the voltage produced by inductor L6 may be greater than the output voltage Vout1 of charge pump 130 which initiates a second stage of the continuous operation of switch BP1. The time constant to charge capacitor C5 may be smaller than the time constant to charge capacitor C4. The difference in time constants between capacitors C5 and C4 may facilitate the use of charge pump 130 and switch Q4 to operate switch BP1 in the first stage until the second stage. In the second stage, the operation may be mainly with the continuous operation of PWM 132, switch Q4 and when the voltage produced by inductor L6 may be greater than the output voltage Vout1 of charge pump 130.

In decision step 1303, diode PD1 makes a first bypass current conduction of inductor L4 in step 1305 which induces voltages across inductors L5 and L6 while bypass switch BP1 may be positively biased with respect to output voltage (VAB) of power module 103. Bypass switch BP1 being positively biased with respect to output voltage (VAB) of power module 103 may signify that power module 103 may be not functioning and needs to have its output bypassed. The induced voltage VL5 of inductor L5 is rectified by diode D2 to charge capacitor C4. The voltage of charged capacitor C4 is applied to the gate (g) of bypass switch BP1, so that bypass switch BP1 is ON for the first bypass current conduction and for both the first and second stages described in further detail below.

The first bypass current conduction of inductor L4 that may be through diode PD1 may be when a low amount of power may be being produced by power sources 101 and respective power modules 103. An example of the low amount of power may be when power sources 101 may be photovoltaic panels that have just begun to be illuminated at dawn for example, or when a photovoltaic panel may be substantially shaded. If enough power may be produced by power sources 101 at decision step 1303, circuit 111 a continues to oscillate with the substantial use of charge pump 130 for several possible cycles until enough power may be produced by power sources 101.

The principal of operation, for either the first bypass current conduction or for the first stage may be that inductor L4 with current flowing through inductor L4 from the first bypass current conduction and/or followed by the use of switch Q4 may be mutually coupled to inductors L5 and L6 via inductor L4. Current flowing through L4 causes current to flow in inductors L5 and L6 (step 1309) and the application of PWM 132 voltage Vout2 to the gate (g) of switch Q4 (step 1311). The application of PWM 132 voltage Vout2 to the gate (g) of switch Q4 may be by virtue of the output voltage Vout1 of charge pump 130 applied to the input (Vin2) of PWM 132. The output voltage Vout1 of charge pump 130 applied to the input (Vin2) of PWM 132 further causes switch Q4 to start to conduct current between source (s) and second terminals of switch Q4 so that Q4 is ON for a time period ton. Discharge of inductor L4 (step 1313) continues in decision step 1315 until the end of time period ton. At end of time period ton the application of PWM 132 voltage Vout2 to the gate (g) of switch Q4 turns Q4 OFF for a time period toff.

Inductors L4, L5 and L6 may be all mutually coupled together on the same core CR1, as such the output of circuit 111 a on inductors L5 and L6 may be coupled back to the input of coupling circuit 120 to inductor L5. The mutual coupling between inductor L4 and inductors L5 and L6 may be such that inductors L5 and L6 have a greater number of turns than inductor L4 so that the voltages induced into inductors L5 and L6 may be much greater by virtue of the well-known transformer equations:

$\frac{{VL}\; 4}{{VL}\; 5} = \frac{{NL}\; 4}{{NL}\; 5}$ and $\frac{{VL}\; 4}{{VL}\; 6} = \frac{{NL}\; 4}{{NL}\; 6}$

Where VL4, VL5 and VL6 are the respective voltages of inductors L4, L5 and L6. NL4, NL5 and NL6 are the respective number of turns of inductors L4, L5 and L6. The greater voltages induced into inductors L5 and L6 may allow for operation of switch BP1, switch Q4, charge pump 130 and PWM 132. Whereas without the greater voltages induced, switch BP1, switch Q4, charge pump 130 and PWM 132 may not be able to operate otherwise.

Until after several possible cycles as described in the steps 1309-1317 above, the voltage produced by inductor L6 and rectified by diode D3 may build up to be greater than the output voltage Vout1 of charge pump 130 rectified by diode D5. When the voltage produced by inductor L6 and rectified by diode D3 may be greater than the output voltage Vout1 of charge pump 130 rectified by diode D5, a second stage begins. The second stage of the continuous operation of switch BP1 begins by the application of voltage rectified by diode D3 applied to the input (Vin2) of PWM 132. The second stage of the continuous operation of switch BP1 continues the same way as described previously in steps 1309-1317, but with substantial use of PWM 132 and switch Q4.

Inherent stabilization of bypass circuit 115 c may be established by virtue of the feedback loop established from the output of circuit 111 a back to the input of circuit 111 a via the rectified outputs of inductors L5 and L6 (across capacitors C4 and C5) responsive to the output of power modules 103 and/or power sources 101. The feedback loop responsive to the output of power modules 103 and/or power sources 101 establishes and maintains the activation of switch BP1 to be ON continuously at step 1007 until a power module 103 and/or power source 103 becomes inactive. Switch BP1 at step 1007 may be forward biased with respect to terminals A and B during bypass mode and the gate (g) of switch BP1 may have voltage applied which may be such that switch BP1 may be continuously ON for the time period that the non-functioning power module 103 is to be bypassed.

Likewise, the feedback loop responsive to the output of power modules 103 and/or power sources 101 establishes and maintains the deactivation of switch BP1 to be OFF continuously at step 1011 until a power module 103 and/or power source 103 becomes once again inactive. Switch BP1 may be reverse biased with respect to terminals A and B during bypass mode and voltage applied to the gate (g) of switch BP1 may be such that switch BP1 is continuously OFF for the time period that the functioning power module 103 is required not to be bypassed at step 1011. Inherent stabilization may occur when switch BP1 may be ON at step 1007, so that as the drain to source voltage Vds falls, the gate (g) to source (s) voltage Vgs also falls. Similarly, stabilization of bypass circuit 115 c may be established when switch BP1 may be OFF at step 1011, so that as the drain (d) to source (s) voltage Vds rises, the gate (g) to source (s) voltage Vgs also rises.

Reference is now made to FIG. 1S, which shows a power system 100 c, according to illustrative embodiments. Connection configuration 104 a shows power source 101 with direct current (DC) output terminals coupled to input terminals of power module 103 at terminals C and D. Power module 103 has a bypass circuit 115 coupled to the output terminals of power module 103 at terminals A and B.

Connection configuration 104 c shows multiple power sources 101 outputs coupled to respective bypass circuits 115 at terminals A and B. The multiple power sources 101 outputs may be coupled in a series connection with direct current (DC) output terminals of the series connection coupled to the input terminals of power module 103 at terminals C and D. A bypass circuit 115 may be coupled to the output terminals of power module 103 at terminals A and B.

The outputs of power modules 103 may be coupled in series to form a series coupled string of power module 103 outputs. The series coupled string of power module 103 outputs, with a voltage output Vstring may be coupled across the input of power device 139. Power device 139 may be a direct current (DC) to DC converter or may be DC to alternating current (AC) inverter supplying power to load 107.

Assuming power sources 101 may be photovoltaic (PV) panels, if a panel is shaded with shade 155, as shown in connection configuration 104 c, the current (Isource) passing through the shaded panel may be offered an alternative, parallel path around the inactive panel, and the integrity of the shaded panel may be preserved. The purpose of bypass circuits 115 coupled across the outputs of panels/power sources 101 may be to be the alternative, parallel path to draw the current away from a shaded panel associated with its respective bypass circuit 115. Bypass circuits 115 become forward biased when their associated shadowed panel becomes reverse biased. Since the panels and the associated bypass circuits 115 may be in parallel, rather than forcing current through the shadowed panels, the bypass circuits 115 draw the current away from the shadowed panels and completes the electrical current to maintain the connection to the next panel in a string of series coupled power sources as shown in connection configuration 104 c. Use of bypass circuits 115 with respect to multiple panels wired in series allows for power to be used from the remaining non-shaded panels whereas placing the bypass circuit on just the output of power module 103 only in connection configuration 104 c may prevent utilization of the power produced by the remaining non-shaded panels.

Similarly, if a power module 103 becomes inactive, the current (Istring) passing through the inactive power module 103 may be offered an alternative, parallel path around the outputs of the inactive power module 103. The purpose of bypass circuits 115 coupled across the outputs of power modules 103 may be to draw the current away from the output of an inactive power module 103 associated with its respective bypass circuit 115. Bypass circuits 115 become forward biased when their associated inactive power module 103 become reverse biased. Since the output of power module 103 and the associated bypass circuits 115 may be in parallel, rather than forcing current through an inactive power module 103, the bypass circuits 115 draw the current away from the output of an inactive power module 103 and completes the electrical current Istring to maintain the connection for current Istring to the next power module 103 output in a string of series coupled power module outputs 103 as shown.

It is noted that various connections are set forth between elements herein. These connections are described in general and, unless specified otherwise, may be direct or indirect; this specification is not intended to be limiting in this respect. Further, although elements herein are described in terms of either hardware or software, they may be implemented in either hardware and/or software. Further, elements of one embodiment may be combined with elements from other embodiments in appropriate combinations or sub-combinations. Examples above have utilized analog circuits for implementation of coupling circuits 120 and circuits 111/111 a used to respectively activate or deactivate a bypass of a non-functioning and functioning power module 103 and/or power source output in a series string of power module 103 and/or power source outputs. Alternatively, the non-functioning power module 103 may utilize auxiliary power circuit 162 and sensors 125 to sense a non-functioning power module 103 output so as to bypass the output of the non-functioning power module 103 output by turning switch BP1 ON (step 1007). Similarly, sensors 125 may be utilized to sense a functioning power module 103 output so as to not bypass the output of the functioning power module 103 output by turning switch BP1 OFF (step 1011).

Reference is now made to FIG. 1T, which shows a photovoltaic (PV) system according to illustrative embodiments. Power system 100T may have multiple PV strings 103T coupled in parallel between power buses 120T and 130T. Each of the PV strings 103 may have multiple power sources 101 and multiple power devices 200. Power sources 101 may include one or more photovoltaic cell(s), module(s), panel(s) or/or photovoltaic shingle(s). Photovoltaic shingles, are solar panels designed to look like and function as conventional roofing materials, such as asphalt shingle or slate, while also producing electricity. Solar shingles are a type of solar energy solution known as building-integrated photovoltaics (BIPV). According to some aspects, power sources 101 shown as PV generators may be replaced by other power sources, for example, direct current (DC) batteries or other DC or alternating current (AC) power sources. Each power device 200 may include a control device and a communication device, and may be operated to disconnect a PV generator connected at the power device inputs when receiving (e.g., via the communication device) a command to disconnect PV generators. Power system 100T may include power buses 120T and 130T, which may be input to system power device 110T.

According to some aspects, system power device 110T may include a DC/AC inverter (e.g., when the input power is DC power), an AC/AC converter (e.g., when the input power is AC power), and may output AC power to a power grid, to a home, or to other destinations. According to some aspects, system power device 110T may include or be coupled to a control device and/or communication device for controlling or communicating with power devices 200. For example, system power device 110 may have a control device such as a microprocessor, digital signal processor (DSP), application specific integrated circuit (ASIC) and/or a field programmable gate array (FPGA) configured to control the operation of system power device 110T.

System power device 110T may further include a communication device (e.g., a power line communication circuit, an acoustic communications device and/or a wireless transceiver) configured to communicate with linked communication devices included in power devices 200 and transmit operational commands and/or receive reports from communication devices included in power devices 200.

According to some aspects, power buses 120T and 130T may be further coupled to energy storage devices such as batteries, supercapacitors, flywheels or other storage devices.

According to some aspects, it may be desirable to bypass (e.g., provide a low-impedance current path across) one or more power sources 101 and/or power devices 200. For example, in case of a malfunctioning or under-producing power source (e.g., PV generator) 101 or a malfunctioning PV power device 200, it may be beneficial to bypass the malfunctioning or under-producing PV module to enable continued power production from power system 100T.

Safety regulations may define a maximum allowable voltage between power buses 120T and 130T and any other point in power system 100T, during both regular operating conditions and during potentially unsafe conditions. Safety regulations may also define a maximum allowable voltage between any two voltage points in power system 100T. In some scenarios, in may be beneficial to bypass (e.g., by short-circuiting and/or disconnecting) one or more of power sources 101 in a PV string 103T in response to an unsafe condition in power system 100T.

Reference is now made to FIG. 2, which illustrates circuitry that may be included in a power device such as power device 200, according to aspects of the disclosure herein. Power device 200 may include power converter 201. Power converter 201 may include a DC/DC converter such as a Buck, Boost, Buck/Boost, Buck+Boost, Cuk, Flyback, charge pump and/or forward converter. According to some aspects, power converter 201 may include a DC/AC converter (also known as an inverter), such as a micro-inverter. Power converter 201 may have two input terminals and two output terminals, which may be the same as the input terminals and output terminals of power device 200. According to some aspects, power device 200 may include an MPPT circuit 205, configured to extract increased power from a power source coupled to power device 200. According to some aspects, power converter 201 may include MPPT functionality. According to some aspects, MPPT circuit 205 may implement impedance matching algorithms to extract increased power from a power source coupled (e.g., directly connected) to the input of power device 200.

Power device 200 may further include a controller 204 such as an analog control circuit, a microprocessor, Digital Signal Processor (DSP), Application-Specific Integrated Circuit (ASIC), and/or a Field Programmable Gate Array (FPGA). Controller 204 may control and/or communicate with other elements of power device 200 over common bus 290. According to some aspects, power device 200 may include circuitry and/or sensor(s)/sensor interface(s) 203 configured to measure parameters directly or receive measured parameters from connected sensor(s)/sensor interface(s) 203 configured to measure parameters on or near the power source, such as the voltage and/or current and/or power output by the power source. According to some aspects, sensor(s)/sensor(s) interfaces 203 may be configured to sense parameters on the output of power device 200. According to some aspects, the power source may be a PV generator including PV cells, and sensor(s)/sensor interface(s) 203 may directly measure or receive measurements of the irradiance received by the PV cells, and/or the temperature on or near the PV generator.

According to some aspects, power device 200 may include communication device 202, configured to transmit and/or receive data and/or commands from other devices such as system power device 110T of FIG. 1T. Communication device 202 may communicate using power line communication (PLC) technology, acoustic communications, or wireless communication technologies such as ZIGBEE™, BLUETOOTH™, Wi-Fi, cellular communication or other wireless methods. According to some aspects, power device 200 may include a memory device 208, for logging measurements taken by sensor(s)/sensor interface(s) 203 to store code, operational protocols or other operating information. Memory device 208 may be flash, electrically erasable programmable read-only memory (EEPROM), random access memory (RAM), solid state devices (SSD) or other types of appropriate memory devices.

Power device 200 may have safety devices 206 (e.g., fuses, circuit breakers and/or Residual Current Detectors). Safety devices 206 may be passive or active. For example, safety devices 206 may include one or more passive fuses disposed within power device 200 and designed to melt when certain current flows through it, disconnecting part of power device 200 to avoid damage. According to some aspects, safety devices 206 may have active disconnect switches, configured to receive commands from a controller (e.g., controller 204) to disconnect portions of power device 200, or configured to disconnect portions of power device 200 in response to a measurement measured by a sensor (e.g., sensor(s)/sensor interface(s) 203). According to some aspects, power device 200 may have an auxiliary power circuit 207, configured to output power suitable for operating other circuitry components (e.g., controller 204, communication device 202). Communication, electrical coupling and/or data-sharing between various components of power device 200 may be carried out over common bus 290.

Power device 200 may have a bypass circuit 209 coupled between the inputs and/or outputs of power converter 201. According to some aspects, bypass circuit 209 may be coupled to the inputs a and b of power device 200. According to some aspects, bypass circuit 209 may be coupled to the outputs c and d of power device 200. In the illustrative power device 200 shown in FIG. 2, a first bypass circuit 209 may be connected between the inputs a and b to power device 200 (e.g. bypass circuit 209 a as shown in FIG. 2A), and a second bypass circuit 209 (e.g., bypass circuit 209 b as shown in FIG. 2B) may be connected between the outputs c and d of power device 200. Bypass circuit 209 may be controlled by controller 204. If an unsafe condition, malfunction and/or underperformance condition is detected, according to some aspects, controller 204 may enable bypass circuit 209, bypassing the inputs a and b to power device 200. Bypass circuit 209 may bypass the inputs a and b to power device 200 by short circuiting the outputs c and d and/or short circuiting the inputs a and b. According to some aspects, bypass circuit 209 may disconnect an input, a or b of power device 200 from the outputs c and d of power device 200 and short circuit the outputs c and d of power device 200.

According to some aspects, bypass circuit 209 may be integrated in power converter 201. For example, power converter 201 may have multiple switches (e.g., metal-oxide-semiconductor field-effect transistors (MOSFETs) such as shown in FIG. 2B) that may be used for power conversion under safe conditions, and may short circuit either the inputs or outputs of power converter 201 under unsafe conditions such as a malfunction condition or an underproduction condition. According to some aspects, bypass circuit 209 may provide bidirectional bypass functionality, while also allowing a regulated voltage for controlling switches of power converter 201.

Reference is made to FIG. 2A, which illustrates circuitry that may be included in bypass circuit 209 a. FIG. 2 illustrates two bypasses 209 as part of power device 200, and in series with power converter 201. According to some aspects, a bypass circuit 209 a may be in parallel to the power device. Bypass circuit 209 a may have a first input A and a second input B, where inputs A and B may be connected to a power string, for example, as part of PV string 103 of FIG. 1T. Bypass circuit 209 a may include a diode bridge 250 including diodes DB1-DB4. A switch (e.g., MOSFET) QB1 may be connected between the output nodes C and D of the diode bridge 250 in bypass circuit 209 a. According to some aspects, power systems supported by embodiments herein, a string current I_(string) may be in DC form. For example, bypass circuit 209 a may be coupled to a power converter connected to a battery, where the battery may be charged (resulting in current flow from node A to node B) and discharged (resulting in current flow from node B to node A). When I_(string) is flowing from point A to point B, I_(string) may enter bypass circuit 209 a, flow through DB2 and reach switch QB1. When bypass circuit 209 a is disabled, switch QB1 is OFF, bypass circuit 209 a may effectively operate as an open circuit, and the string current I_(string) may flow through and be processed by a power converter (e.g., a micro-inverter) coupled in parallel with bypass circuit 209 a (not explicitly shown in FIG. 2A, but shown in FIG. 3). When bypass circuit 209 a is enabled, switch QB1 is ON and I_(string) flows through switch QB1 and diode DB4, out of bypass circuit 209 a to point B. In some scenarios (e.g. discharging a battery), I_(string) may flow from point B to point A. I_(string) may enter bypass circuit 209 a and flow through diode DB1 and reach switch QB1. When bypass circuit 209 a is disabled, switch QB1 is OFF and bypass circuit 209 a is an open circuit. When bypass circuit 209 a is enabled, switch QB1 is ON and I_(string) may flow through switch QB1 and diode DB3, out of bypass circuit 209 a to point A.

According to some aspects, I_(string) may be in an AC form (e.g., when power converter 201 is a DC/AC converter), and the I_(string) current may flow from A to B during a first part of a cycle and from B to A during a second part of the cycle. In each flow direction of I_(string), because of the diode bridge 250 in bypass circuit 209 a, the voltage V_(B+) may be larger than V_(B−) which may prevent any current from flowing through the passive diode in switch QB1. Because of the diode bridge 250 in bypass circuit 209 a, the voltage on switch QB1 may be positive (V_(B+)−V_(B−)>0). Because the positive voltage across switch QB1 may always be positive, the voltage drop across switch QB1 may be provided to a controller (e.g. an analog or digital controller) configured to drive switch QB1 to provide a bypass path, according to illustrative features disclosed below.

Reference is now made to FIG. 2B, which illustrates bypass circuit 209 b, where the inputs of bypass circuit 209 b are connected to a string, for example PV string 103 of FIG. 1T. Bypass circuit 209 b may have a MOSFET bridge 260 including MOSFETs QB2-QB5. The outputs of the MOSFET bridge 260 in bypass circuit 209 b may be connected with a switch QB1 between them. According to some aspects, I_(string) may be in DC form. In a scenario where I_(string) is flowing from point A to point B, I_(string) may enter bypass circuit 209 b, flow through QB4 (which may be ON or OFF) and reach switch QB1. When bypass circuit 209 b is disabled, MOSFET QB1 may be OFF and bypass circuit 209 b may be an open circuit. When bypass circuit 209 b is enabled, switch QB1 is ON and I_(string) may flow through switch QB1 and MOSFET QB2 (which may be ON or OFF), and may flow through bypass circuit 209 b to point B. In some scenarios, I_(string) may flow from point B to point A. I_(string) may enter bypass circuit 209 b and flow through switch QB3 (that may be ON or OFF) and reach switch QB1. When bypass circuit 209 b is disabled, switch QB1 may be OFF and bypass circuit 209 b may be an open circuit. When bypass circuit 209 b is enabled, switch QB1 may be ON and I_(string) may flow through switch QB1 and MOSFET QB5 (that may be ON or OFF) through bypass circuit 209 b to point A. According to some aspects, I_(string) may be in an AC form and the I_(string) current may flow from A to B during a first part of a cycle and from B to A during a second part of the cycle. In each direction of I_(string), because of the MOSFET bridge 260 in bypass circuit 209 b, the voltage level V_(B+) may be larger than voltage level V_(B−) which may prevent substantial current from flowing through the passive diode in MOSFET QB1. Because of the MOSFET bridge 260 in bypass circuit 209 b, the voltage on MOSFET QB1 may be positive (V_(B+)−V_(B−)>0). Each one of MOSFETs QB2-QB5 may be ON or OFF when bypass circuit 209 b is enabled and/or disabled, where when MOSFETs QB2-QB5 are OFF current may flow through the passive diodes in MOSFETs QB2-QB5, and when MOSFETs QB2-QB5 are ON the current may flow through the MOSFETs themselves. MOSFETs QB1-QB5 may be powered by an external auxiliary power circuit such as auxiliary power circuit 207 of FIG. 2.

According to some aspects, MOSFETs QB2-QB5 of bypass circuit 209 b may be part of an inverter (e.g., a microinverter). For example, power converter 201 of FIG. 2 may be an inverter. When bypass circuit 209 b is disabled, switches QB2-QB5 may be switched at an inverter frequency (e.g., 10 kHz, 20 kHz, 100 kHz, 200 kHz or even higher) and switch QB1 may be OFF. When bypass circuit 209 b is enabled, switches QB2-QB5 may switch at a frequency of a grid-frequency of current flowing through I_(string) (e.g., 50 Hz or 60 Hz) and switch QB1 may be ON, short-circuiting outputs C and D. According to some aspects, bypass circuit 209 b may be connected in parallel to a power device, where when bypass circuit 209 b is disabled switch QB1 is OFF and I_(string) may flow through the power device parallel to bypass circuit 209 b. When switch QB1 is ON and bypass circuit 209 b is enabled, the outputs of power device parallel to bypass circuit 209 b (which may be the same as points A and B) may be short-circuited, allowing the current I_(string) to flow through bypass circuit 209 b and bypass the power device.

Reference is now made to FIG. 2C, which shows part of a power device 210 according to one or more illustrative aspects of the present disclosure. Power device 210 may include power converter 211, which may be the same as power converter 201 of FIG. 2. According to some aspects, power device 212 may have a bypass circuit 212 a configured to bypass the inputs of power device 210. Bypass circuit 212 a may be configured to provide a bypass path across the outputs of power device 210 and/or disconnect an input of power device 210 from the outputs of power device 210. According to some aspects, power device 210 may have a bypass circuit 212 b configured to bypass power device 210 and/or power converter 211. Bypass circuit 212 b may be configured to provide a bypass path by short circuiting the outputs of power device 210.

According to some aspects, bypass circuit 212 b may be coupled to a bypass circuit having a bimetallic strip BMS1. Bimetallic strip BMS1 may include two materials with different expansion coefficients bonded together. Bimetallic switch BMS1 may operate as a switch, such that when BMS1 is heated at a first temperature, the first material including BMS1 may curve in a first direction and at a second temperature the second material including BMS1 may curve in a second direction. For example, the first material may curve at a first temperature of 40° C. and the second material may curve at a second temperature of 200° C. BMS1 may be configured to short circuit the outputs of power device 212 out1 and out2 in response to a state of overheating (for example, when the temperature surrounding BMS1 is over 200° C.) and to disconnect outputs out1 and out2 when the temperature is beneath 200° C. The coupling of bypass circuit 212 b with BMS1 may be such that BMS1 is positioned in proximity to a certain element in bypass circuit 212 b (e.g., MOSFET or diode). The proximity of BMS1 to bypass circuit 212 b may be such that BMS1 may sense a temperature level similar to the certain element in bypass circuit 212 b. When bypass circuit 212 b is enabled and current is flowing through bypass circuit 212 b the temperature of certain elements may rise, and in a state of overheating, BMS1 may be configured to switch ON, creating another path for the current to flow through other than bypass circuit 212 b, which may lower the temperature at the element of bypass circuit 212 b. According to some aspects, power device 210 may have a bypass circuit 212 a. According to some embodiments, bypass circuit 212 a may be configured to short circuit the outputs of power device 210. Parallel to bypass circuit 212 a may be a bimetallic switch BMS2. BMS2 may be similar to or the same as BMS1, where BMS1 may be placed between the outputs of power device 210 out1 and out2 and BMS2 may be placed between the inputs of power device 210 in1 and in2. BMS2 may be positioned in proximity to a certain element in bypass circuit 212 a (e.g., MOSFET). The proximity of BMS2 to bypass circuit 212 a may be such that BMS2 may sense a temperature level similar to the certain element in bypass circuit 212 a. When bypass circuit 212 a is enabled and current is flowing through bypass circuit 212 a, the temperature of certain elements (e.g. a switch QB1) may rise, and in a state of possible or potential overheating, BMS2 may be configured to switch ON, creating another path for the current to flow through, which may lower the temperature in bypass circuit 212 b. According to some aspects BMS3 may be coupled to the certain element in bypass circuit 212 a.

According to some aspects, power device 210 may include bypass circuit 212 a. A bimetallic strip BMS3 may be coupled to bypass circuit 212 a. BMS3 may be similar to BMS1, where BMS1 may be placed between the outputs of power device 210 out1 and out2 and BMS3 may be placed between the low side of the inputs of power device 210, node in3, and power converter 211 low side, node in2. According to some aspects, BMS3 may be positioned in proximity to a certain element of bypass circuit 212 a. In a scenario where bypass circuit 212 a is enabled, and the inputs to power device 210 are short circuited, the temperature of the certain element in bypass circuit 212 a may rise. BMS3 may be “normally ON” during normal operating conditions, and configured to create an open circuit and mechanically disconnect an input of power device 210 from the outputs of power device 210 which may lower the current flowing through bypass circuit 212 a and specifically the certain element in bypass circuit 212 a, and by lowering the current the temperature on the certain element may drop. According to some aspects, power device 210 may have only a bypass circuit including BMS1. According to some aspects, power device 210 may have a bypass circuit including BMS2. According to some aspects, power device 210 may have a bypass circuit BMS3. According to some aspects, power device 210 may have a bypass circuit including more than one bimetallic switch, such as BMS2 and BMS3.

Bimetallic switches BMS1 and/or BMS2 and/or BMS3 may be used as a primary bypass mechanism of power device 210, or as a backup bypass mechanism while the primary backup mechanism may be similar to or the same as bypass circuit 209 a of FIG. 2A and/or 209 b of FIG. 2B, where backup bypass mechanism may be needed in a scenario where the primary bypass circuit fails, overheats, etc.

According to some aspects, one or more of bimetallic switches BMS1-BMS3, may be replaced with an active electronic switch, for example, a metal-oxide-semiconductor field-effect transistor (MOSFET), insulated-gate bipolar transistor (IGBT), Bipolar Junction Transistor (BJT), relay switch etc. According to some aspects, BMS1 and/or BMS2 may be replaced with a passive switch, for example, a diode.

Reference is made again to FIG. 2. According to some aspects, power device 200 may have bypass circuit 209 coupled to the outputs of power device 200. Bypass circuit 209 may have a bypass circuit similar to or the same as bypass circuit 209 a of FIG. 2A and/or bypass circuit 209 b of FIG. 2B. In some embodiment, bypass circuit 209 may have a bimetallic strip similar to or the same as bimetallic strip BMS1 of FIG. 2C.

Reference is made again to FIG. 2. According to some aspects, power device 200 may have bypass circuit 209 coupled to the inputs of power device 200. Bypass circuit 209 may have a bypass circuit similar to or the same as bypass circuit 209 a of FIG. 2A and/or bypass circuit 209 b of FIG. 2B. In some embodiment, bypass circuit 209 may have a bimetallic strip similar to or the same as bimetallic strip BMS2 of FIG. 2C.

Reference is now made to FIG. 3, which shows a block diagram of part of a power device 300, according to aspects of illustrative embodiments. Power device 300 may be the same as or similar to power device 200 of FIG. 2, and may include power converter 301, auxiliary power circuit 302, bypass circuit 303, controller 304, and sensor(s)/sensor interface(s) 305, which may be similar to or the same as power converter 201, auxiliary power circuit 207, bypass circuit 209, controller 204, and sensor(s)/sensor interface(s) 203, respectively. Controller 304 may be operatively connected to sensor(s)/sensor interface(s) 305, whereby sensor(s)/sensor interface(s) 305 may be operatively connected, to sense parameters of power device 300. Power converter 301 converts input power on terminals V_(in+), V_(in−) to an output power on the output of converter 301 as string current I_(string). Bypass 303 may be connected across the output of converter 301. Power to operate bypass 303 as well as power converter 301, controller 304 and/or sensor(s)/sensor interface(s) 305 may be provided by auxiliary power circuit 302.

According to some aspects, controller 304 may receive a value of a parameter measured by sensor(s)/sensor interface(s) 305, for example temperature, voltage and/or current. Controller 304 may compare the value of the measured parameter with a maximum threshold and determine the value of the measured parameter as an unsafe value (e.g., a temperature indicative of overheating of the system, such as 200° C.). Controller 304 may enable bypass circuit 303 in response to determining that there is a malfunction and/or underproduction condition in power device 300. Bypass circuit 303 may short circuit the outputs of power converter 301 and/or outputs of power device 300. According to some aspects, bypass circuit 303 may be powered by auxiliary power circuit 302 with an output voltage of V_(g). The output voltage of auxiliary power circuit 302 may be determined by controller 304, while controller 304 may further determine which switches in bypass circuit 303 to turn ON and OFF and when to turn ON and OFF. Auxiliary power circuit 302 may have an input voltage of V_(AUX)=V_(B+)−V_(B−), where V_(B+) and V_(B−) may be according to the voltage value at the output of bypass circuit 303.

According to some aspects (not explicitly shown), power converter 301 may include an inverter, which may include a MOSFET bridge (e.g. bridge 260 of FIG. 2B). Power converter 301 may serve as a power converter and/or inverter when power device 300 is enabled and providing power to a solar string having current I_(string). When power device is being bypassed, power converter 301 may serve as the bypass circuit. In an embodiment where power converter 301 serves as a bypass circuit, power converter 301 may include a switch positioned between the two outputs of the MOSFET bridge (e.g. QB1 of FIG. 2B) in power converter 301. The switch positioned between the two outputs of the MOSFET bridge may be ON when bypass is enabled and maybe OFF when bypass is disabled.

Reference is now made to FIG. 3A, which shows an illustration of an auxiliary power circuit 302 a, bypass circuit 303 a and controller 304 as part of a power device. Auxiliary power circuit 302 a and bypass circuit 303 a may be the same as or similar to auxiliary power circuit 302 and bypass circuit 303 of FIG. 3. Controller 304 may receive a signal indicating the bypass circuit 303 a should be enabled, or controller 304 may independently determine that bypass circuit 303 a should be enabled. Bypass circuit 303 a may be implemented in a similar way to bypass circuit 209 b, including a bridge 370 of switches (e.g. MOSFETs) QB2-QB5 where the outputs of the bridge 370 (nodes C and D), are coupled to each other via switch (e.g. MOSFET) QB1. A first input to auxiliary power circuit 302 a may electrically couple to a first output of bypass circuit 303 a (node C) which may be coupled to the source terminal of switch QB1. A second input to auxiliary power circuit 302 a may electrically couple to a second output of bypass circuit 303 a (node D) which may be coupled to the drain terminal of switch QB1. Auxiliary power circuit 302 a may include a power converter 306. Power converter 306 may be an AC/DC converter and/or a DC/DC converter. Power converter 306 may be configured to convert power from a lower voltage level e.g. 0.01[V] to a higher voltage level (e.g., 5 V, 12 V, 100 V, 220 V, and higher). The power at the outputs of bypass circuit 303 a may have a voltage value of V_(B+)−V_(B−) that may be the same voltage on the inputs to auxiliary power circuit 302 a. The input power to auxiliary power circuit 302 a may be converted by power converter 306 and may be output by auxiliary power circuit 302 a. Auxiliary power circuit 302 a may be configured to provide power to one or more circuits and/or mechanisms in the power device, such as controller 304 and switches QB1-QB5 of bypass circuit 303 a. Controller 304 may be configured to determine how much power to feed each switch of switches QB1-QB5. For example, I_(string) may be an AC current with a value of: I_(string)=10 [A] at a frequency of: f=40 [Hz] and may flow into a first input of bypass circuit 303 a. Bypass circuit 303 a may be disabled, switch QB1 may be OFF, and auxiliary power circuit 302 a may draw power from the outputs of bypass circuit 302 b having a voltage value of, for example, V=V_(B+)−V_(B−)=0.5[V]. Auxiliary power circuit 302 a may draw current according to the voltage required by switches QB1-QB5 (as determined by controller 304). Auxiliary power circuit 302 a may output a voltage value of V_(g) with regard to a neutral point, ground or other point. According to some aspects, controller 304 may switch switches QB2-QB5 at a frequency of f=50 [Hz], such that switches QB4 and QB2 are ON when QB3 and QB5 are OFF, and switches QB2 and QB4 are OFF when QB3 and QB5 are ON. Auxiliary power circuit 302 a may draw current from bypass circuit 303 a with a value of, for example, I_(AUX)=0.01[A]. The current I_(AUX) may be used to power controller 304 as well as auxiliary 302 a and bypass circuit 303 a. According to some aspects, auxiliary power circuit 302 a may include a controller configured to control the switching of switches QB1-QB5. In a scenario where controller 304 decides to enable bypass circuit 303 a, switches QB2-QB5 may be powered and switched at the same rate as when bypass circuit 303 a is disabled. The voltage value of V=V_(B+)−V_(B−) may change because QB1 may be turned ON, creating a voltage drop depending on characteristics (e.g., the drain-to-source resistance) of switch QB1, for example, V=V_(B+)−V_(B−)=0.1V. Power converter 306 in auxiliary power circuit 302 a may be configured to convert input ultra-low voltages such as 0.1V or even lower. When controller 304 enables bypass circuit 303 a and commands auxiliary power circuit 302 a to turn switch QB1 ON, I_(AUX) may grow accordingly to I_(AUX)=0.05 A, to supply enough power to turn switch QB1 ON.

Reference is now made to FIG. 3B, which shows part of power device 300 b according to illustrative embodiments. Power device 300 b may include power converter 301 b, auxiliary power circuit 302 b and controller 304 b which may be the same as or similar to power converter 201, auxiliary power circuit 207 and controller 204 of FIG. 2. According to some aspects, power device 300 b may be coupled to power source 310. Power source 310 may be a source which at times provides power and at times receives power, for example a battery. According to some aspects, I_(string) may be in DC form during each period of time. When power source 310 is providing power, the current I_(string) may flow from A to B and when power source 310 is receiving power, I_(string) may flow from B to A. In an embodiment where I_(string) is in DC form, power converter 301 b may be a DC/DC converter. Power device 300 b may have a bypass circuit 303 b configured to bypass power converter 301 b and/or power source 310. Bypass circuit 303 b may be a component of power device 300 b or power converter 301 b or an independent device configured to couple to the outputs of power device 300 b or power converter 301 b.

Reference is now made to FIG. 3C, which shows a bypass circuit according to illustrative embodiments. Bypass circuit 303 b of FIG. 3B may be implemented similarly to bypass circuit 303 c of FIG. 3C, having a first switch SB1 and a second switch SB2 connected in series. Switches SB1 and SB2 may be coupled to outputs A and B, and nodes C and D may be coupled to the outputs of power converter 301 b. Bypass circuit 303 b may be configured to turn switches SB1 and SB2 ON when bypass circuit 303 b is enabled, and turn switches SB1 and SB2 OFF when bypass 303 b is disabled. Bypass circuit 303 b may receive power from auxiliary power circuit 302 b. Controller 304 b may be configured to decide to enable bypass circuit 303 b and/or disable bypass circuit 303 b. When bypass circuit 303 b is disabled and power device 300 b is transferring power from power source 310 to the outputs A and B of power device 300 b or transferring power from outputs A and B of power device 300 b to power source 310, the voltage drop across bypass circuit 303 b may be the same as or similar to the voltage between points A and B, for example, 40[V]. Auxiliary power circuit 302 b may have the same or a similar voltage as bypass circuit 302 b, and may transfer power to components in power device 300 b, such as controller 304 b. When bypass circuit 303 b is enabled, outputs A and B are short circuited using switches SB1 and SB2. The voltage between points A and B may drop to 1[V]. The voltage across auxiliary power circuit 302 b may drop accordingly. Auxiliary power circuit 302 b may be configured to transfer power under low voltages to bypass circuit 303 b.

According to some aspects, I_(string) may be in AC form. Bypass circuit 303 b may be implemented in a manner the same as or similar to bypass circuit 303 a. Power converter 301 b may be a DC/AC inverter. When bypass circuit 303 b is disabled, switch QB1 (of FIG. 3A) may be OFF and power converter 301 b may receive I_(string) from outputs of power device 300 b, A and B. Switches QB4 and QB2 may be ON, powered by auxiliary power circuit 302 b. When bypass circuit 303 b is enabled, switch QB1 may turned ON by controller 304 b and auxiliary power circuit 302 b.

Reference is now made to FIG. 4, which illustrates part of a power device 400 according to illustrative embodiments. Power device 400 may include power converter 401, auxiliary power circuit 402, bypass circuit 403, and controller 404 that may be the same as or similar to power converter 201, auxiliary power circuit 207, bypass circuit 209, nodes a, b, c, d and controller 204 of FIG. 2, respectively. Bypass circuit 403 may be coupled to the outputs of power device 400 and/or the outputs of power converter 401 and may be configured to bypass power converter 401.

According to some aspects, auxiliary power circuit 402 may receive power from the inputs to power device 400, a and b, with a voltage value of: V_(in)=V_(in+)−V_(in−). Power may be transferred from a power generator (e.g., power generator 101 of FIG. 1) to the inputs a and b of power device 400, at a voltage value of V_(in), and the power may flow from a power generator such as power generator 101 of FIG. 1A. Auxiliary power circuit 402 may be electrically coupled to the outputs of bypass circuit 403, and may receive power from bypass circuit 403 with at voltage value of V_(B)=V_(B+)−V_(B−). According to some aspects, auxiliary power circuit 402 may extract power from the inputs to power device 400, A and B, rather than from the outputs of bypass circuit 403 that receives power from the outputs of power device 400, c and d, for example, if the current I_(string) is in AC form while auxiliary power circuit requires current and voltage in DC form. According to some aspects, auxiliary power circuit 402 may receive power from the inputs to power device 400, controller 404 may disable bypass circuit 403, for example, bypass circuit 403 may comprise multiple MOSFETs (i.e., as shown in bypass circuit 209 b of FIG. 2A), and controller 404 may keep the MOSFETs OFF and not switch them ON and OFF.

In some scenarios, auxiliary power circuit 402 might not be able to receive power from the inputs to power device 400, for example, if the power generator configured to output power to power device 400 through the inputs of power device 400 is disconnected from power device 400. In such a scenario (e.g., where power from the inputs to power device 400 is not available), auxiliary power circuit 402 may be powered by power from the outputs of bypass circuit 403. According to some aspects, auxiliary power circuit 402 may have a logic block (e.g., circuit 410 shown in FIG. 4A) configured to extract power from the inputs of power device 400 or from bypass circuit 403.

Reference is now made to FIG. 4A, which illustrates a circuit 410 configured to disable and enable a bypass circuit. Circuit 410 may be part of a power device, such as power device 400. The bypass circuit may be enabled when a switch QB1 is ON and disabled when switch QB1 is OFF. Switch QB1 may be the same as or similar to switch QB1 of FIG. 3A. Switch QB1 may be a MOSFET disposed between points DD and GG. Switch QB1 may be configured to bypass a power source 411 and/or a power device including circuit 410. Power source 411 may have a first output AA and a second output point GG. Point GG may be used as a reference point in circuit 410 and may be referenced to as a relative ground. Circuit 410 may have a resistor R11 disposed between output AA and a point BB. Point BB may be an input to an amplifier Amp1. Amplifier Amp1 may have a negative input and a positive input. Point BB may be at the negative input to amplifier Amp1. The positive input to amplifier Amp1 may be point H. Between points HH and GG may be a diode D13 configured to allow current to flow from GG to H and to apply a set voltage (e.g., 0.3V, 0.5V, 0.7V, 1V) difference between GG and H, setting a reference voltage on the positive input to amplifier Amp1. Resistor R12 may be disposed between points BB and GG. Resistors R11 and R12 may be configured to function as voltage divider in relation to the voltage of power source 411, V_(A)−V_(G). Amplifier Amp1 may have a first output at point EE. Switch QB1 may have a drain terminal connected to point DD, a source terminal connected to point GG and a gate terminal connected to point FF. Resistor R13 may be disposed between points EE and FF and resistor R14 may be disposed between points FF and GG. V_(g) may be the voltage at point FF, where it may be defined by the output voltage from amplifier Amp1. V_(g) may be the voltage at the gate to switch QB1. Point CC may be the positive power supply on amplifier Amp1 and point GG may be the negative power supply on amplifier Amp1. Resistor R15 may be disposed between points HH and DD. Between point CC and DD may be a diode D12 configured to set a voltage difference between point CC and point DD. A second diode D11 may be disposed between points AA and CC.

Amplifier Amp1 may be connected between terminals CC and GG for receiving operational power from power source 411 via diode D11 or from the voltage across switch QB1, via diode D12. According to the illustration of FIG. 4A, if the voltage across power source 411 is higher than the voltage across switch QB1, the operational power for amplifier Amp1 will be drawn from power source 411, and if the voltage across power source 411 is lower than the voltage across switch QB1, the operational power for amplifier Amp1 will be drawn from across switch QB1. This may provide the advantage of enabling power supply from power source 411 if power source 411 is available (which may increase efficiency), and enabling power supply from across switch QB1 if power source 411 is unavailable (e.g., if power source 411 is a disconnected or malfunctioning power source, or a shaded photovoltaic generator).

Optionally, diodes D12 and D11 may be removed, and terminal CC may be directly connected to terminal DD (enabling drawing operational power to amplifier Amp1 from across switch QB1) or to terminal AA (enabling drawing operational power to amplifier Amp1 from power source 411).

Reference is now made to FIG. 4B, which shows a method 420 for enabling bypass according to illustrative embodiments. Method 420 may be implemented by one or more circuits, analog and/or digital, for example circuit 410 of FIG. 4A. Step 420 may include providing power to an amplifier and/or an operational amplifier (e.g., Amp1 of FIG. 4A). The operational amplifier may have a positive power supply, and a negative power supply. According to some aspects, the positive power supply may be equal to the absolute value of the negative power supply. According to some aspects, the positive power supply may be different than the absolute value of the negative power supply, for example, the positive power supply may be 1[V] compared to a relative ground and the negative power supply may be 0[V] compared to the relative ground. The negative power supply may be connected to the negative end of a power source. The negative end of the power source may be related to as a relative ground. The positive power supply may draw power from a node common to a first diode and a second diode. The first diode (e.g. D11 of FIG. 4A) may be connected to the output of the power source, and the second diode (e.g. D11 of FIG. 4A) may be connected to the positive side of a switch configured to enable bypass when ON and disable bypass when OFF (e.g. QB1 of FIG. 4A). The switch may be a MOSFET where the drain may be a positive side of the switch, and the source of the switch may be the negative side of the switch. The positive power supply of the amplifier may get the voltage value of the higher voltage between the power source and the positive side of the switch.

Step 422 of method 420 may include inputting a first voltage into the negative input of the operational amplifier and a second voltage to the positive input of the operational amplifier. The positive voltage may be related to as a reference voltage. The reference voltage may be connected to the relative ground with a diode (e.g. D13 of FIG. 4A). The diode may be configured to maintain a set voltage relative to the ground. The positive input to the amplifier may be connected to the positive end of the power source through a voltage divider (e.g. R11 and R12 of FIG. 4A), to maintain a voltage level appropriate to the voltage levels that the operational amplifier may receive. The operational amplifier may be configured to compare the voltage level received from the positive end of the power source with the reference voltage. The voltage level need for the negative input to be greater than the reference positive input may be determined by the voltage divider connecting the positive end of the power source with the negative input to the amplifier, and the diode connecting the relative ground and the positive input. In a scenario where the negative input is greater than the positive input, the operational amplifier may output a voltage value similar to the relative ground. The output of the amplifier may be connected to the relative ground with two resistors in series (e.g. R13 and R14 of FIG. 4A). The switch configured to enable bypass may have a gate connected to a point between the two resistors in series, where the two resistors may be configured to be a voltage divider. In such a scenario, where the output voltage of the amplifier is the similar to the relative ground, the voltage difference between the output of the amplifier, the voltage in between the two resistors and the relative ground may be substantially zero with regard to voltage needed to activate the switch. As long as power is supplied to the operational amplifier, the comparison between the negative input and the positive input to the amplifier is done.

In a scenario where the negative input to the amplifier is less than the positive input, the output from the amplifier may be similar to the positive power supply. The positive power supply may be substantially greater than the relative ground, creating a differential voltage between the output of the amplifier and the relative ground. The voltage divider connected to the output of the amplifier may set a voltage level (depending on the ratio between the resistors of the voltage divider) at the gate of the bypass switch high enough to activate the switch and enable the bypass circuit, step 423. Bypass may continue as long as the voltage level at the negative input of the amplifier is lower than the reference voltage level at the positive input to the amplifier.

Reference is now made to FIG. 5, which shows a method 500 for enabling bypass according to an embodiment. A power system may have one or more strings of one or more power devices connected in parallel and/or series. Each one of the power devices may be coupled to a power generator. Each one of the power devices may extract power from the power generators to the common string. The common string may carry AC and/or DC current and/or voltage. Method 500 may begin at step 501, which may include sensor(s)/sensor interface(s) coupled to or housed in one of the one or more power devices sensing operational parameters of the power device and the power generator coupled to the power device. Operational parameters may include input voltage current and/or power to the power device, temperature in and/or surrounding the power device, output voltage current and/or power of the power device, voltage current and/or power in the power device, etc. The sensed values by the sensor(s)/sensor interface(s) may be provided to a controller.

The controller, in step 502, may evaluate the signal(s) received from the sensor(s)/sensor interface(s) and determine if the measurements are representative of a safe or unsafe, functional or dysfunctional operating condition. If the controller determines the measurements represent a safe operating condition, the controller may control the power device to extract power from the coupled power generator and sense the operational parameters at step 501. If the controller determines the values of the measured values represent an unsafe, malfunctioning or underproduction operating condition, the controller may activate the bypass of the power device.

The bypass of the power device may be configured to short-circuit the outputs of the power device, and/or disconnect the inputs of the power device from the power generator and/or short circuit the inputs of the power device. According to some aspects, the power device may have a communication device configured to receive and/or send signals to other devices in the power system. The communication device, in step 503, may receive a bypass signal, or stop receiving a keep-alive signal. The power device may be configured to extract power and couple to the common string as long as long as the keep-alive signal is being received. When the keep-alive signal stops or when the bypass signal is received, the controller may be configured to enable the bypass and/or shutdown the power device, and go into bypass, step 504.

Enabling the bypass of the power device may include drawing power for an auxiliary power circuit configured to provide power to the bypass circuit. The bypass circuit may include one or more switches (e.g., MOSFETs, BJTs, IGBTs, etc.) configured to open and short circuit the bypass circuit, such as switches QB1-QB5 of FIG. 3A. According to some aspects, the auxiliary power circuit may be configured to draw power from the inputs of the power device. The inputs of the power device may be connected to a power source. According to some aspects, the power source may output power at a level high enough to power the auxiliary power circuit, even in a scenario where the power source is under producing and is to be bypassed. According to some aspects, the auxiliary power circuit may be configured to draw power from the outputs of the power device. A controller may be configured to determine if to draw power from the inputs of the power device or from the outputs, step 505. The controller may be configured to draw power from the inputs of the power device as long as the power source is outputting enough power to provide and power the auxiliary power circuit.

In some embodiments, where the inputs to the auxiliary power circuit are coupled to the inputs of the power device, step 505 may be followed by step 506 a. The auxiliary power circuit may draw power needed to activate the bypass from the inputs to the power device. The auxiliary power circuit may include a power converter configured to output power suitable to power the bypass circuit that may include providing power to the switches in the bypass circuit. The power drawn from the inputs to the power device to the auxiliary power circuit may be converted to suitable voltage levels needed to activate the bypass circuit. The controller may activate the switches of the bypass circuit according to form of current flowing into the bypass from the common string, using the power drawn from the auxiliary.

According to some aspects, the controller may decide to draw power from the outputs of the power device and not to draw power from the inputs of the power device, step 506 b. The bypass circuit may include a first and a second input coupled to the outputs of the power device. The bypass circuit may further include a first output and a second output coupled to the inputs of the auxiliary power circuit. The auxiliary power circuit may have a power converter configured to output power suitable to power the bypass circuit that may include providing power to the switches in the bypass circuit. The bypass circuit may draw power from the common string and output the amount of power needed to feed the auxiliary power circuit. After receiving the amount of power needed to power the auxiliary power circuit, the controller may activate the switches accordingly. For example, the current and voltage from the common string may be DC current and voltage. The controller may turn multiple switches ON and keep multiple switches OFF depending on the direction of the power flow. According to some aspects, the current and/or voltage may be in an AC form and the direction of the current may be bidirectional. The bypass circuit may be designed as a rectifier configured to ensure a constant direction of current on the outputs of the bypass circuit. The controller may switch the switches in the bypass circuit ON and OFF at a rate that may be proportional to the rate of the current (e.g., the rate of the current may be 50 Hz and the switching rate of the switches may be 50 Hz).

According to some aspects, the auxiliary may be coupled to the outputs of the bypass and to the inputs of the power device. The auxiliary power circuit may have a logic block configured to output either the voltage of the input to the power device or the output of the bypass. For example, the logic block may be configured to perform an “OR” operation on both the voltage of the input to the power device and the output of the bypass, and output the greater one of the two. According to some aspects, the logic block may be configured to output the voltage of the input to the power device as long as the voltage is over a minimum threshold (e.g., 0.1[V]), otherwise output the voltage of the output to the bypass.

After drawing power to the auxiliary power circuit, step 507 includes activating the bypass. Activating the bypass may be carried out by the controller by turning a switch from OFF to ON and keeping it ON as long as the bypass is enabled. The bypass may be enabled as long as an enablement signal is received, a disable signal has not been received and/or a keep-alive signal has not been received.

Reference is now made to FIG. 6A, which shows an implementation of a bypass circuit 115, according to aspects include in the disclosure herein. Coupling circuit 120 may include coupling the gate (g) of switch BP1 (of FIG. 1G) to cathode of diode D3 and a first end of resistor R4. The anode of diode D3 may couple to the cathode of diode D1, a first end of capacitor C3 and the gate (g) of switch Q8. A second end of resistor R4 may couple to a second end of capacitor C3 and terminal B. The second end of capacitor C3 may couple to a first end of inductor L3 and a second end of inductor L3 may couple to the anode of diode D1. The drain (d) of switch BP1 may couple to the cathode of diode PD1 at terminal A to give a return connection RET1. The anode of diode PD1 may couple to the source (s) of switch BP1, the anode of diode BD2 that belongs to switch Q8 and the source (s) of switch Q8. The drain (d) of switch Q8 may couple the source (s) of switch Q9 and to a first side of resistor R3. The gate (g) of switch Q9 may be coupled to circuit 606. The cathode of diode PD2 may be coupled to a first side of resistor R1. A second side of resistor R1 may be coupled to the drain (d) of switch Q9 and a first end of inductor L1 of circuit 111. Switch BP1 may be a metal oxide semiconductor field effect transistor (MOSFET), which may include diode PD1 or which may not include a diode. Similarly switches Q6, Q7 and Q9 may be MOSFETs, which include a diode like diode PD2 or which may not include a diode. Switch Q9 may be a junction gate field-effect transistor (J-FET). According to some aspects, bypass circuit 115 may not have circuit 606, switch Q8 and resistor R1.

In circuit 111, a second end of inductor L1 may couple to the drains (d) of switches Q6 and Q7. The sources (s) of Q6 and Q7 may be coupled together to give a return connection RET2. A first end of resistor R2 may couple between the gate of switch Q7 and the source (s) of switch Q7. The gate (g) of switch Q6 may couple to a first end of capacitor C2. A second end of capacitor C2 may couple to a first end of inductor L2 and a first end of capacitor C1. A second end of inductor L2 may provide return connection RET3. A second end of capacitor C1 may couple to the gate of switch Q2. Return connections RET1, RET2 and RET3 may couple together to form a return path that may be separate to terminal B at the source(s) of switch BP1. Separation between the return path and terminal B in bypass circuit 115, along with the integration of bypass circuit 115 across the input of a power device 200, may be achieved by disposing switch Q8 and diode PD2 between terminal B and inductor L1. Switches BP1, Q6 and Q7 may be metal oxide semiconductor field effect transistors (MOSFETs) and switch Q9 may be a junction field effect transistor (JFET).

According to some aspects, inductors L1, L2 and L3 may be mutually coupled on the same magnetic core. In effect, the coupling between inductor L1 to L2 and then inductor L2 to L3 may provide a possible function of coupling between the output of circuit 111 and coupling circuit 120. Therefore, the output of circuit 111 across inductor L1 may be coupled back to the input of coupling circuit 120 via the mutual inductance between inductor L1 and inductor L3 and also coupled to inductor L2 via the mutual coupling between inductor L1 and inductor L2. The mutual inductance between inductor L1 and inductor L2 and voltages induced into inductor L2 drive the gates (g) of switches Q6 and Q7 via the coupling of respective capacitors C2 and C1. The mutual coupling between inductor L1 and inductors L2 and L3 may be such that inductors L2 and L3 have a greater number of turns across the common magnetic core than inductor L1 does, so the voltages induced into inductors L2 and L3 are greater by virtue of the transformer equations:

$\frac{{VL}\; 1}{{VL}\; 2} = \frac{{NL}\; 1}{{NL}\; 2}$ and $\frac{{VL}\; 1}{{VL}\; 3} = \frac{{NL}\; 1}{{NL}\; 3}$

where VL1, VL2 and VL3 are the respective voltages of inductors L1, L2 and L3, where NL1, NL2 and NL3 are the respective number of turns of inductors L1, L2 and L3.

The greater voltages induced into inductors L2 and L3 by virtue of the greater number of turns NL2 and NL3 may allow for operation of switches BP1, Q6, and Q7, whereas without the greater voltages induced, switches BP1, Q6 and Q7 might not be able to operate otherwise. Inductor L2 and capacitors C1 and C2 in circuit 111 function as a Colpitts oscillator. The frequency of oscillation given by:

$f_{o} = \frac{1}{2\pi \sqrt{L_{2}\left( \frac{C_{1}C_{2}}{C_{1} + C_{2}} \right)}}$

Inductors L1, L2, L3, and capacitors C1 and C2 may be chosen so that a frequency of oscillation for circuit 111 may be between 1 and 4 Kilohertz (KHz). The low frequency of oscillation of circuit 111 may therefore, provide low losses in the switching of Q6, Q7 and Q8. Alternatively, capacitor C1 may be replaced with another inductor so that circuit 111 may be implemented as a Hartley oscillator. Inductor L3 of circuit 120 may be built on the same core as inductors L1 and L2 in circuit 111, diode D1 may be used to rectify voltages induced on inductor L3 that may be by virtue of the mutual coupling between inductor L3 to inductors L1 and L2 of circuit 111. The rectified pulses may drive the voltage (Vgs) between gate (g) and source (s) of the MOSFET of switch BP1 to turn switch BP1 ON for continuous conduction of switch BP1 at step 1007 (see FIG. 1H).

Connected to the gate of switch Q9 may be a second side of resistor R3 and circuit 606. Circuit 606 may be coupled to the gate (g) of switch Q8 by the anode of diode D4. The output of a comparator comp may be coupled to the cathode of diode D4. Comparator comp may have a reference voltage Vref at the positive input to comparator comp, and Vd at the negative input to comparator comp. Vd may be the voltage from a power source and/or the voltage from the power device housing bypass circuit 115. The positive power supply may be coupled to a first side of resistor R5 and to the cathode of a zener diode Dz. A second side of resistor R5 may be coupled to Vs. Vs may represent the output voltage of the power source coupled to the power device. The anode of diode Dz may be connected to a reference point, where resistor R5 and diode Dz are configured to regulate the positive power supply. The voltage output of comparator comp may be configured to either turn switch Q9 ON or OFF. When comparator comp outputs a voltage of −Vb switch Q9 is ON and when comp outputs a positive voltage relative to Vs, depending on the value of R5, switch Q9 is OFF.

Reference is now made again to FIG. 1T with method 1000 of FIG. 1H applied to the further details of coupling circuit 120, switch BP1 and circuit 111 in bypass circuit 115 shown in FIG. 1G, according to illustrative embodiments. At step 1003, switch BP1 may be coupled across the outputs of a power device 200 where there may be a series string of power device 200 outputs. Switch BP1 is not active in step 1003.

At decision step 1005, specifically a first bypass current conduction of diode PD1 may be an indication of power device 200 and/or power source 101 not functioning correctly. Consequently, the flow of current (I_(string)) through an inactive power device 200 output may become restricted. As a result of restricted current flow, the voltage outputs of the other power devices 200 in the string may attempt to push the current through their outputs and through the inactive power device 200 output. The attempt at pushing current flow of current may be caused by an increase in voltage output of the other power device 200, which may cause diode PD1 to become forward biased so that a first bypass current conduction of current occurs through diode PD1. Diode PD1 becoming forward bias also results in diode PD2 also being forward biased. The forward biasing of diode PD2 allows the utilization of circuit 111 to initiate a continuous operation of switch BP1. Detailed description of the operation of circuit 111 is described later on in the descriptions which follow.

At step 1007, circuit 111 may initiate the continuous operation of switch BP1. As soon as body diode PD1 conducts, Q6 and/or Q7 may be ON, and circuit 605 may maintain the continuous operation of switch BP1 so that the MOSFET of switch BP1 is ON such that the voltage (Vds) between drain (d) and source (s) of switch BP1 remains low, e.g., from about 10 millivolts (mV) substantially up to 200 mV. A comparison between Vds of 10 mV of switch Q1 and a forward voltage drop 0.7V of a bypass diode to bypass a string current (I_(string)) of 25 Amperes gives bypass power losses of 0.25 Watts and 17.5 Watts, respectively. As such, operation of switch BP1 in bypass circuit 115 and other bypass circuit embodiments described below provide efficient bypass circuits that may allow the bypassing power sources and/or other circuit elements without incurring significant losses by the bypass itself. Bypassing power sources and/or other circuit elements without incurring significant losses may be significant when compared to other ways of providing a bypass that may include the use of bypass diodes, for example.

At step 1007, return connections RET1, RET2 and RET3 may couple together to form a return path rtn that may be a separate return path to that provided at terminal B at the source (s) of switch BP1. Separation between the return path and terminal B between coupling circuit 120 and circuit 111 may be by switch Q9 and diode BD2. Consequently, oscillations of circuit 111 may build on the drains of switches Q6 and/or Q7, while the return path for the oscillations may be provided on the sources(s) of switches Q7 and/or Q6.

At decision step 1009, if inactive power device 200 remains inactive, then the MOSFET of switch BP1 remains ON so that switch BP1 remains activated at step 1007. At decision step 647, if switch BP1 remains activated at step 1007, power from auxiliary power circuit 207 may be isolated from being supplied to the inactive power device 200. However, when power device 200 starts to become active, for example when a panel becomes unshaded that may be sensed by sensors/sensor interfaces 203 and may turn switch Q8 OFF, power from auxiliary power circuit 207 may be allowed to be resupplied to the switches of power device 200 to allow the functioning of power device 200. Both the MOSFET and body diode PD1 of switch BP1 and diode PD2 at this point may become reverse biased. The reverse bias voltages of both the MOSFET and diode PD1 of switch BP1 applied to the input of circuit 111 at the anode of diode PD2 may cause the ceasing of the oscillations of circuit 111. The output oscillations of circuit 111 ceasing when feedback to the input of switch BP1 via coupling circuit 120 may be sufficient to cause the MOSFET of switch BP1 to switch OFF, so that switch BP1 is de-activated at step 1011. Alternatively, sensors/sensor interfaces 203 under control of controller 204 or some other controller may sense the reverse bias voltages of both the MOSFET and diode BD1 of switch BP1. As a result of the reverse biases being sensed, switch BP1 may be switched OFF and power from auxiliary power circuit 207 may be allowed to be resupplied to the switches of power device 200 to allow power device 200 to function as normal. The reduction of voltage applied to the gate of the MOSFET of switch BP1 causes the MOSFET to turn OFF. With the power devices 200 functioning normally switch BP1 is now inactive (OFF) but still coupled at terminals A and B (step 1003).

Reference is now made to FIG. 6B, which shows circuit 111, and a flow chart of FIG. 1K, according to illustrative embodiments. Shown is the connection of circuit 111 to coupling circuit 604 and circuit 606. Step 1007 (see also FIG. 1H, which shows the steps prior to and after step 1007) occurs if a power device 200 does not work, so that switch BP1 draws the current in the series string (I_(string)) in a path around the output of an inactive power device 200. Circuit 111 may be the same as described with regard to FIG. 1G, and may be coupled to bypass switch BP1. Switches Q6 and Q7 may be biased with resistor R2. In operation of circuit 111 when switch BP1 is OFF and a power device 200 is working correctly at step 1011, switch Q9 and diode PD2 may block leakage current through bypass switch BP1 and block reverse voltage across bypass switch BP1 when the voltage at terminal A may be much greater than the voltage at terminal B. Conversely when a power device 200 is not working at step 1007, switch Q9 is operated by the rectified output provided by diode D1 so that diode PD2 is bypassed by switch Q9 when switch Q9 may be ON. Switch Q9 OFF during step 1007 provides a block of leakage current through bypass switch BP1. Switch Q9 being ON may additionally compensate for any drop in voltage across terminals A and B as a result of switch BP1 being turned ON and being maintained as ON during step 1007 so as to give headroom for circuit 111 to oscillate. Switch Q9 and its operation is ignored and is to be considered to be ON, in order to simplify the following description.

In decision step 1203, if a low amount of power is being produced by a power source 101 and respective power device 200 compared to other power sources 101 and respective power devices 200 in a series string of power device 200 outputs, a first bypass current conduction may therefore be through diode PD1. Similarly, if the power source 101 and respective power device 200 has a failure the first bypass current conduction may also be through diode BD1.

At step 1205, the first bypass current conduction may induce a voltage VL1 across inductor L1 since diode PD2 is similarly forward biased as diode BD1. At step 637 b, bypass switch BP1 may be positively biased with respect to output voltage (VAB) of power device 200. Bypass switch BP1 being positively biased with respect to output voltage (VAB) of power device 200 may be a result of power device 200 not functioning. The first bypass current conduction to provide the bypass of current through bypass switch BP1 may therefore be through diode PD1, followed by the conduction of inductor L1 via diode PD2 and then by the conduction of inductor L1 by use of switch Q6 in a first stage of operation of bypass switch BP1.

An example of the low amount of power may be when power sources 101 may be photovoltaic panels that have just begun to be illuminated (e.g., at dawn) or when a photovoltaic panel may be substantially and/or partially shaded. Shading may reduce power generated by a power source 101 (e.g., reducing the power generated by, for example, 20%, 50% or even close to 100% of the power generated by an unshaded power source). If enough power may be produced by power sources 101 in decision step 637 a, circuit 605 may continue to oscillate with an initial use of switch Q6 for a number of times according to the steps of 637 c-637 g described below as part of the first stage of operation of switch BP1 until the second stage of operation where switch Q7 and/or Q6 are used. Q6 may be implemented using a junction field effect transistor (JFET) rather than a MOSFET since a JFET compared to a MOSFET may have a lower bias input current compared to a MOSFET and a JFET may conduct between source (s) and drain (d) when the voltage between gate (g) and source (Vgs) is substantially zero. Q6 may also be implemented using a depletion mode FET.

Following on from the first stage with the use of Q6, steps 1209, 1211, 1213, 1215, and 1217 are implemented with the use of switch Q7 and/or switch Q6 as part of a second stage of operation of switch BP1. The principal of operation for both the first stage and the second stage is that inductor L1 is mutually coupled to inductors L3 and L2 when current flows through inductor L1. The mutual coupling is such that when current flows through inductor L1, current flows in inductor L2 and induces a voltage VL2 into inductor L2. Voltage VL2 may charge the gate (g) of switches Q7 and/or switch Q6 (at step 637 c) via capacitors C1 and/or C2. The charging of the gate (g) of Q7 and/or switch Q6 may cause switch Q7 and/or switch Q6 to start to conduct current between source (s) and drain (d) of switch Q7 and/or switch Q6 so that Q7 and/or switch Q6 is ON (step 637 g) for a time period ton.

The energy induced into inductor L1 during ton may be discharged by a time constant τ [L1]

τ[L1]=L1×Req

where Req may be the equivalent resistance that includes resistor R1 and the respective resistances (Rds) between drain (d) and source (s) when switch Q6 and/or Q7 may be ON. The value of respective resistances (Rds) between drain (d) and source (s) when switch Q7 and/or Q6 may be ON may be derived from manufacturer data sheets for the particular devices chosen for switches Q7 and Q6 as part of the design of circuit 605. Discharge of inductor L1 (step 1213) may continue in decision step 1215 until voltage VL2 of inductor L2 in decision step 637 f drops below the threshold voltage of Q7 and/or switch Q6 which makes Q7 and/or switch Q6 switch OFF (step 1217) for a time period toff. Q7 and/or switch Q6 drain (d) voltage then may begin to increase by the ratio:

$\frac{ton}{t\; {off} \times {VAB}}$

so that voltage may again increase on L2 for a time defined by a time constant τ [L2], after which switch Q7 and/or switch Q6 conducts again (step 1209), which may create the oscillation of circuit 111. The time constant τ [L2] may be given by:

τ[L2]=√{square root over (L2×Ceq)}

where Ceq may be the equivalent capacitance that includes capacitors C1 and C2 and the parasitic capacitances of switches Q7 and/or Q6. Parasitic capacitances of switches Q7 and/or Q6 may be derived from manufacturer data sheets for the particular devices chosen for switches Q7 and Q6 as part of the design of circuit 111. Parasitic capacitances of switches Q7 and/or Q6 may or may not be a significant factor in the desired value of time constant τ [L2]. Inductor L1 coupled to inductor L3 may cause a voltage to be induced in inductor L3 when current flows through inductor L1. The voltage induced into inductor L3 may be rectified by diode D1. The rectified voltage of diode D1 may be applied to the gate (g) of bypass switch BP1 via diode D3 and resistor R4, which may turn bypass switch BP1 to be ON (step 1007).

Reference is now made to FIG. 6C, which illustrates a power device 600 according to aspects of the disclosure herein. Power device 600 may be the same as or similar to power device 200 of FIG. 2. According to some aspects, power device 600 may have a first input In1 and a second input In2 configured to input power from a power source 610 to power device 600. Power device 600 may have a first output Out1 and a second output Out2. Power device 600 may be coupled to a power system (e.g. power system 100) with a current (I_(string)) via outputs Out1 and Out2. According to some aspects, power device may include a full bridge 601. Full bridge 601 may include a bridge of four switches (e.g. MOSFETs) S62-S65. Full bridge 601 may be configured to transfer power from power source 610 to outputs Out1 and Out2 (e.g., full bridge 601 may function as an inverter). In some scenarios, bypass circuit 603 may be disabled, for example, voltage Vd of circuit 606 may be greater than Vref causing the output voltage of comparator comp to be −Vb turning switch Q8 OFF (where Vd, Vref, circuit 606, comp, Vb and Q8 appear in FIG. 6B). In a scenario where power source 610 is producing power at a sufficient level and power device 600 is operating correctly, the voltage of terminal A (Va) may be configured to be higher than the voltage of terminal B (Vb).

Current may flow from outputs Out1 and/or Out2 of power device 600 to power source 610 and power may flow back to outputs Outl and/or Out2. In some scenarios, bypass circuit 603 may be enabled by turning switch Q8 of FIG. 6B ON. Switches S61-S64 of full bridge 601 may have bypass diodes (similar to or the same as diode PD1 of switch BP1 of FIG. 6B). Current may enter power device 600 through output Outl and/or Out2 and may reach point A flowing through the bypass diodes of switches S62 or S63. Entering bypass circuit 603, the current may flow from terminal A to terminal B through circuit 605, resistor R1 and switch Q8 (which appear in FIG. 6B). Flowing from terminal A to terminal B may provide power to switch BP1 through coupling circuit 120 turning switch BP1 ON and providing a path with lower impedance than through circuit 111 of FIG. 1G, while providing enough power through circuit 111 and coupling circuit 120 of FIG. 6A for holding switches Q9 of FIG. 6B and BP1 ON. Current may flow from point B back to output Outl and/or Out2 through bypass diodes of switches S64 and/or S61. According to some aspects, power on outputs Outl and Out2, of power device 600 may be in AC form, and power source 610 may be a DC power source. Full bridge 601 may be configured to convert output current from AC to DC when entering power device 600, and may be configured to output power from power source 610 through power device 600 and out of outputs Outl and Out2 of power device 600.

Reference is now made to FIG. 6D, which illustrates aspects of power device 600. Switch BP1 of FIG. 6B may be replaced by a first switch S65 and a second switch S66. Switches S65 and S66 may be the same as switch BP1. Terminal A may be coupled to the drain (d) of switch S65 and terminal B may be coupled to the drain (d) of switch S66. The source (s) of switch S65 may be coupled to the source (s) of switch S66. The gate (g) of switch S65 may be coupled to the gate (g) of switch S66 as well as to the cathode of diode D3 and a first side of resistor R4. A second side of resistor R4 may be coupled to the sources of switch S65 and switch S66 as well as the second side of capacitor C3 and the first end of inductor L3. The bypass circuit of FIG. 6D may be different than the circuit depicted in FIG. 6B in that switch BP1 of FIG. 6B is replaced by switches S65 and S66 of FIG. 6D, and point B of FIG. 6B is attached to the drain terminal of switch S66 of FIG. 6D instead of the source terminal of switch BP1 of FIG. 6B.

According to some aspects, power source 610 may function as a load as well as a source (e.g., a battery that functions as a load when charging and functions as a source when discharging). When power source 610 is functioning as a source, I_(string) may flow from terminal A to terminal B, and when power source 610 is functioning as a consumer, I_(string) may flow from terminal B to terminal A. When I_(string) is flowing from terminal A to terminal B and bypass circuit 603 is disabled, switches S65 and S66 may be OFF and the bypass diode of switch S65 may block the current from flowing through switches S65 and S66. Switch Q8 of FIG. 6B may be OFF preventing current from flowing through circuit 111 of FIG. 6B from terminal A to terminal B. When current I_(string) is flowing from terminal B to terminal A, and bypass circuit 115 is disabled, switches S65 and S66 may be OFF and the bypass diode of switch S66 may block current from flowing from terminal B to terminal A through switches S65 and S66. When bypass circuit 115 is enabled, meaning switch Q8 is turned ON current may flow from terminal A to terminal B and/or vice versa through circuit 111 and may provide power to switches S65 and S66 through coupling circuit 120 of FIG. 6A. When enough power is provided to the gates (g) of switches S65 and S66, switches S65 and S66 may turn ON and I_(string) may flow through switches S65 and S66.

Having switches S65 and S66 in series may make it easier to design coupling circuit 120 and circuit 111 and to select the values of the components for one or more reasons. One reason may be creating a symmetric circuit. When switches S65 and S66 are coupled in series, the direction of current I_(string) may not affect the voltage values and polarity of Va and Vb. For example, I_(string) may be flowing from terminal B to terminal A and power source 610 may be functioning as a source. The voltage difference between Va and Vb may be determined according to the operation of power device 600, e.g. 50V. In a scenario where power source 610 is acting as a load, the voltage difference between Va and Vb may be 50V with I_(string) flowing from A to B. If switch BP1 of bypass circuit 115 (FIG. 1G) was not replaced with switches S65 and S66 the voltage difference may be Va−Vb=50V when the power source is functioning as a source and I_(string) is flowing from terminal A to terminal B. However, when power source 610 is functioning as a load the voltage difference between Va and Vb may be substantially the voltage of body diode PD1 of switch BP1, which may be far lower, for example, 0.7V. Designing bypass circuit 115 to have a constant voltage drop between terminals A and B regardless of the direction of current flow may make it simpler and cheaper to design a circuit designed to convert to voltage between terminals A and B to a voltage used for operating the bypass circuit.

According to some aspects, ensuring power to the auxiliary power circuit may solve one or more problems and/or provide an advantage over auxiliary power provided only when connected to the inputs to the power device. For example, in a scenario where a power generator was disconnected from a power device, the auxiliary power circuit may provide an option of bypassing the disconnected portion of the string rather than disconnecting the entire string, or by creating an open circuit section in a string that has a danger of arcing. Another example of a possible advantage according to certain aspects may be providing auxiliary power at night when the PV power generator may not provide substantial power.

According to certain aspects, the power device may test the power generators to determine whether they are operating in a normal state or not, in which the testing may require auxiliary power. Providing auxiliary power may enable the ability to perform testing on one or more power generators and bypassing one or more power generators in the same string. It is noted that various connections are set forth between elements herein. These connections are described in general and, unless specified otherwise, may be direct or indirect; this specification is not intended to be limiting in this respect. Further, although elements herein are described in terms of either hardware or software, they may be implemented in either hardware and/or software. Additionally, elements of one embodiment may be combined with elements from other embodiments in appropriate combinations or sub combinations.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are described as example implementations of the following claims. 

What claimed is:
 1. A bypass circuit, comprising: a switch operatively coupled across a first input of a circuit and an output of a power source, and a coupling circuit including a first output operatively coupled to the switch, the coupling circuit including a second input coupled to a second output of the circuit via a feedback path, wherein the switch is biased to provide a bypass responsive to a voltage of the first input of the circuit and a voltage of the power source.
 2. The bypass circuit of claim 1, further comprising: a second switch operatively connected between a third output of the coupling circuit and a third input of the circuit, wherein the second switch is configured to block leakage current through the switch and block reverse voltage across the switch from the circuit.
 3. The bypass circuit of claim 1, wherein the switch is continuously biased across the first input to selectively be either ON or OFF to provide thereby the bypass across the first input responsive to a voltage of the power source.
 4. The bypass circuit of claim 1, wherein the coupling circuit includes a transformer adapted to increase a voltage on the second output from the first input, wherein the voltage enables operation of the switch below its minimal operating parameters.
 5. A power device comprising: a power converter comprising input terminals and output terminals, wherein the power converter is configured to receive power at the input terminals from a power generator and convert the power to the output terminals, a controller configured to monitor one or more parameters at the input terminals or the output terminals of the power converter; and a bypass circuit coupled to the outputs of the power device, wherein the controller is configured to activate the bypass circuit based on the one or more parameters.
 6. The power device of claim 5, wherein the power device is configured to convert direct current (DC) power to alternating current (AC) power.
 7. The power device of claim 5, wherein the controller is configured to activate the bypass circuit in response to the parameters indicating one or more of a malfunctioning condition, an underproduction condition, or a potentially unsafe condition.
 8. The power device of claim 5, further comprising: at least one sensor configured to sense an operating condition of the power device and to provide an indication of the sensed operating condition to the controller, wherein the controller is configured to output at least one signal to the bypass circuit when the sensed operating condition is indicative of an abnormal operating condition.
 9. The power device of claim 5, further comprising an auxiliary power circuit, wherein the auxiliary power circuit is configured to provide power to the bypass circuit.
 10. The power device of claim 6, wherein the bypass circuit is powered via voltage and current on the output of the power device.
 11. The power device of claim 5, wherein the bypass circuit comprises a diode bridge configured to rectify current and voltage at the output of the power device.
 12. The power device of claim 5, wherein the bypass circuit comprises a MOSFET bridge configured to rectify current and voltage at outputs of the power device.
 13. The power device of claim 9, wherein the auxiliary power circuit further comprises a logic block configured to receive power from the input of the power device and the output of the bypass circuit, wherein the logic block is configured to determine where to draw power from.
 14. A method comprising: receiving a signal; determining, based on the signal, to enable a bypass circuit for a power device; drawing power by an auxiliary power circuit, wherein the drawn power is configured to power the bypass circuit; and activating the bypass circuit using the drawn power.
 15. The method of claim 14, wherein the activating the bypass circuit comprises switching on a switch.
 16. The method of claim 15, wherein the switch is a MOSFET.
 17. The method of claim 14, wherein the drawing power comprises connecting the auxiliary power circuit to outputs of the bypass circuit.
 18. The method of claim 17, wherein the power comprises AC power.
 19. The method of claim 14, wherein the drawing power comprises connecting the auxiliary power circuit to inputs of the power device, and wherein the power device houses the bypass circuit.
 20. The method of claim 14, further comprising comparing a voltage on inputs of the power device and a voltage on outputs of the bypass circuit to determine which one corresponds to a higher voltage, and drawing the power with the higher voltage. 